WebGPU

W3C Candidate Recommendation Snapshot,

More details about this document
This version:
https://www.w3.org/TR/2024/CR-webgpu-20241219/
Latest published version:
https://www.w3.org/TR/webgpu/
Editor's Draft:
https://gpuweb.github.io/gpuweb/
History:
https://www.w3.org/standards/history/webgpu/
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Editors:
(Google)
(Google)
(Mozilla)
Former Editors:
(Apple Inc.)
(Mozilla)
(Apple Inc.)
Test suite:
WebGPU CTS
Participate:
File an issue (open issues)

Abstract

WebGPU exposes an API for performing operations, such as rendering and computation, on a Graphics Processing Unit.

Status of this document

This section describes the status of this document at the time of its publication. A list of current W3C publications and the latest revision of this technical report can be found in the W3C technical reports index at https://www.w3.org/TR/.

Feedback and comments on this specification are welcome. GitHub Issues are preferred for discussion on this specification. Alternatively, you can send comments to the GPU for the Web Working Group’s mailing-list, public-gpu@w3.org (archives).

This document was published by the GPU for the Web Working Group as a Candidate Recommendation Snapshot using the Recommendation track. This document will remain a Candidate Recommendation at least until in order to ensure the opportunity for wide review.

This document defines a stable implementation target for the API, which the GPU for the Web Working Group plans to iterate over and extend in subsequent revisions. It might also evolve based on feedback gathered as its associated test suite evolves.

The group expects to demonstrate implementation of each feature in at least two deployed browsers on top of modern GPU system APIs. The test suite will be used to build an implementation report.

Publication as a Candidate Recommendation does not imply endorsement by W3C and its Members. A Candidate Recommendation Snapshot has received wide review, is intended to gather implementation experience, and has commitments from Working Group members to royalty-free licensing for implementations.

This document was produced by a group operating under the W3C Patent Policy. W3C maintains a public list of any patent disclosures made in connection with the deliverables of the group; that page also includes instructions for disclosing a patent. An individual who has actual knowledge of a patent which the individual believes contains Essential Claim(s) must disclose the information in accordance with section 6 of the W3C Patent Policy.

This document is governed by the 03 November 2023 W3C Process Document.

1. Introduction

This section is non-normative.

Graphics Processing Units, or GPUs for short, have been essential in enabling rich rendering and computational applications in personal computing. WebGPU is an API that exposes the capabilities of GPU hardware for the Web. The API is designed from the ground up to efficiently map to (post-2014) native GPU APIs. WebGPU is not related to WebGL and does not explicitly target OpenGL ES.

WebGPU sees physical GPU hardware as GPUAdapters. It provides a connection to an adapter via GPUDevice, which manages resources, and the device’s GPUQueues, which execute commands. GPUDevice may have its own memory with high-speed access to the processing units. GPUBuffer and GPUTexture are the physical resources backed by GPU memory. GPUCommandBuffer and GPURenderBundle are containers for user-recorded commands. GPUShaderModule contains shader code. The other resources, such as GPUSampler or GPUBindGroup, configure the way physical resources are used by the GPU.

GPUs execute commands encoded in GPUCommandBuffers by feeding data through a pipeline, which is a mix of fixed-function and programmable stages. Programmable stages execute shaders, which are special programs designed to run on GPU hardware. Most of the state of a pipeline is defined by a GPURenderPipeline or a GPUComputePipeline object. The state not included in these pipeline objects is set during encoding with commands, such as beginRenderPass() or setBlendConstant().

2. Malicious use considerations

This section is non-normative. It describes the risks associated with exposing this API on the Web.

2.1. Security Considerations

The security requirements for WebGPU are the same as ever for the web, and are likewise non-negotiable. The general approach is strictly validating all the commands before they reach GPU, ensuring that a page can only work with its own data.

2.1.1. CPU-based undefined behavior

A WebGPU implementation translates the workloads issued by the user into API commands specific to the target platform. Native APIs specify the valid usage for the commands (for example, see vkCreateDescriptorSetLayout) and generally don’t guarantee any outcome if the valid usage rules are not followed. This is called "undefined behavior", and it can be exploited by an attacker to access memory they don’t own, or force the driver to execute arbitrary code.

In order to disallow insecure usage, the range of allowed WebGPU behaviors is defined for any input. An implementation has to validate all the input from the user and only reach the driver with the valid workloads. This document specifies all the error conditions and handling semantics. For example, specifying the same buffer with intersecting ranges in both "source" and "destination" of copyBufferToBuffer() results in GPUCommandEncoder generating an error, and no other operation occurring.

See § 22 Errors & Debugging for more information about error handling.

2.1.2. GPU-based undefined behavior

WebGPU shaders are executed by the compute units inside GPU hardware. In native APIs, some of the shader instructions may result in undefined behavior on the GPU. In order to address that, the shader instruction set and its defined behaviors are strictly defined by WebGPU. When a shader is provided to createShaderModule(), the WebGPU implementation has to validate it before doing any translation (to platform-specific shaders) or transformation passes.

2.1.3. Uninitialized data

Generally, allocating new memory may expose the leftover data of other applications running on the system. In order to address that, WebGPU conceptually initializes all the resources to zero, although in practice an implementation may skip this step if it sees the developer initializing the contents manually. This includes variables and shared workgroup memory inside shaders.

The precise mechanism of clearing the workgroup memory can differ between platforms. If the native API does not provide facilities to clear it, the WebGPU implementation transforms the compute shader to first do a clear across all invocations, synchronize them, and continue executing developer’s code.

NOTE:
The initialization status of a resource used in a queue operation can only be known when the operation is enqueued (not when it is encoded into a command buffer, for example). Therefore, some implementations will require an unoptimized late-clear at enqueue time (e.g. clearing a texture, rather than changing GPULoadOp "load" to "clear").

As a result, all implementations should issue a developer console warning about this potential performance penalty, even if there is no penalty in that implementation.

2.1.4. Out-of-bounds access in shaders

Shaders can access physical resources either directly (for example, as a "uniform" GPUBufferBinding), or via texture units, which are fixed-function hardware blocks that handle texture coordinate conversions. Validation in the WebGPU API can only guarantee that all the inputs to the shader are provided and they have the correct usage and types. The WebGPU API can not guarantee that the data is accessed within bounds if the texture units are not involved.

In order to prevent the shaders from accessing GPU memory an application doesn’t own, the WebGPU implementation may enable a special mode (called "robust buffer access") in the driver that guarantees that the access is limited to buffer bounds.

Alternatively, an implementation may transform the shader code by inserting manual bounds checks. When this path is taken, the out-of-bound checks only apply to array indexing. They aren’t needed for plain field access of shader structures due to the minBindingSize validation on the host side.

If the shader attempts to load data outside of physical resource bounds, the implementation is allowed to:

  1. return a value at a different location within the resource bounds

  2. return a value vector of "(0, 0, 0, X)" with any "X"

  3. partially discard the draw or dispatch call

If the shader attempts to write data outside of physical resource bounds, the implementation is allowed to:

  1. write the value to a different location within the resource bounds

  2. discard the write operation

  3. partially discard the draw or dispatch call

2.1.5. Invalid data

When uploading floating-point data from CPU to GPU, or generating it on the GPU, we may end up with a binary representation that doesn’t correspond to a valid number, such as infinity or NaN (not-a-number). The GPU behavior in this case is subject to the accuracy of the GPU hardware implementation of the IEEE-754 standard. WebGPU guarantees that introducing invalid floating-point numbers would only affect the results of arithmetic computations and will not have other side effects.

2.1.6. Driver bugs

GPU drivers are subject to bugs like any other software. If a bug occurs, an attacker could possibly exploit the incorrect behavior of the driver to get access to unprivileged data. In order to reduce the risk, the WebGPU working group will coordinate with GPU vendors to integrate the WebGPU Conformance Test Suite (CTS) as part of their driver testing process, like it was done for WebGL. WebGPU implementations are expected to have workarounds for some of the discovered bugs, and disable WebGPU on drivers with known bugs that can’t be worked around.

2.1.7. Timing attacks

2.1.7.1. Content-timeline timing

WebGPU does not expose new states to JavaScript (the content timeline) which are shared between agents in an agent cluster. Content timeline states such as [[mapping]] only change during explicit content timeline tasks, like in plain JavaScript.

2.1.7.2. Device/queue-timeline timing

Writable storage buffers and other cross-invocation communication may be usable to construct high-precision timers on the queue timeline.

The optional "timestamp-query" feature also provides high precision timing of GPU operations. To mitigate security and privacy concerns, the timing query values are aligned to a lower precision: see current queue timestamp. Note in particular:

2.1.8. Row hammer attacks

Row hammer is a class of attacks that exploit the leaking of states in DRAM cells. It could be used on GPU. WebGPU does not have any specific mitigations in place, and relies on platform-level solutions, such as reduced memory refresh intervals.

2.1.9. Denial of service

WebGPU applications have access to GPU memory and compute units. A WebGPU implementation may limit the available GPU memory to an application, in order to keep other applications responsive. For GPU processing time, a WebGPU implementation may set up "watchdog" timer that makes sure an application doesn’t cause GPU unresponsiveness for more than a few seconds. These measures are similar to those used in WebGL.

2.1.10. Workload identification

WebGPU provides access to constrained global resources shared between different programs (and web pages) running on the same machine. An application can try to indirectly probe how constrained these global resources are, in order to reason about workloads performed by other open web pages, based on the patterns of usage of these shared resources. These issues are generally analogous to issues with Javascript, such as system memory and CPU execution throughput. WebGPU does not provide any additional mitigations for this.

2.1.11. Memory resources

WebGPU exposes fallible allocations from machine-global memory heaps, such as VRAM. This allows for probing the size of the system’s remaining available memory (for a given heap type) by attempting to allocate and watching for allocation failures.

GPUs internally have one or more (typically only two) heaps of memory shared by all running applications. When a heap is depleted, WebGPU would fail to create a resource. This is observable, which may allow a malicious application to guess what heaps are used by other applications, and how much they allocate from them.

2.1.12. Computation resources

If one site uses WebGPU at the same time as another, it may observe the increase in time it takes to process some work. For example, if a site constantly submits compute workloads and tracks completion of work on the queue, it may observe that something else also started using the GPU.

A GPU has many parts that can be tested independently, such as the arithmetic units, texture sampling units, atomic units, etc. A malicious application may sense when some of these units are stressed, and attempt to guess the workload of another application by analyzing the stress patterns. This is analogous to the realities of CPU execution of Javascript.

2.1.13. Abuse of capabilities

Malicious sites could abuse the capabilities exposed by WebGPU to run computations that don’t benefit the user or their experience and instead only benefit the site. Examples would be hidden crypto-mining, password cracking or rainbow tables computations.

It is not possible to guard against these types of uses of the API because the browser is not able to distinguish between valid workloads and abusive workloads. This is a general problem with all general-purpose computation capabilities on the Web: JavaScript, WebAssembly or WebGL. WebGPU only makes some workloads easier to implement, or slightly more efficient to run than using WebGL.

To mitigate this form of abuse, browsers can throttle operations on background tabs, could warn that a tab is using a lot of resource, and restrict which contexts are allowed to use WebGPU.

User agents can heuristically issue warnings to users about high power use, especially due to potentially malicious usage. If a user agent implements such a warning, it should include WebGPU usage in its heuristics, in addition to JavaScript, WebAssembly, WebGL, and so on.

2.2. Privacy Considerations

There is a tracking vector here. The privacy considerations for WebGPU are similar to those of WebGL. GPU APIs are complex and must expose various aspects of a device’s capabilities out of necessity in order to enable developers to take advantage of those capabilities effectively. The general mitigation approach involves normalizing or binning potentially identifying information and enforcing uniform behavior where possible.

A user agent must not reveal more than 32 distinguishable configurations or buckets.

2.2.1. Machine-specific features and limits

WebGPU can expose a lot of detail on the underlying GPU architecture and the device geometry. This includes available physical adapters, many limits on the GPU and CPU resources that could be used (such as the maximum texture size), and any optional hardware-specific capabilities that are available.

User agents are not obligated to expose the real hardware limits, they are in full control of how much the machine specifics are exposed. One strategy to reduce fingerprinting is binning all the target platforms into a few number of bins. In general, the privacy impact of exposing the hardware limits matches the one of WebGL.

The default limits are also deliberately high enough to allow most applications to work without requesting higher limits. All the usage of the API is validated according to the requested limits, so the actual hardware capabilities are not exposed to the users by accident.

2.2.2. Machine-specific artifacts

There are some machine-specific rasterization/precision artifacts and performance differences that can be observed roughly in the same way as in WebGL. This applies to rasterization coverage and patterns, interpolation precision of the varyings between shader stages, compute unit scheduling, and more aspects of execution.

Generally, rasterization and precision fingerprints are identical across most or all of the devices of each vendor. Performance differences are relatively intractable, but also relatively low-signal (as with JS execution performance).

Privacy-critical applications and user agents should utilize software implementations to eliminate such artifacts.

2.2.3. Machine-specific performance

Another factor for differentiating users is measuring the performance of specific operations on the GPU. Even with low precision timing, repeated execution of an operation can show if the user’s machine is fast at specific workloads. This is a fairly common vector (present in both WebGL and Javascript), but it’s also low-signal and relatively intractable to truly normalize.

WebGPU compute pipelines expose access to GPU unobstructed by the fixed-function hardware. This poses an additional risk for unique device fingerprinting. User agents can take steps to dissociate logical GPU invocations with actual compute units to reduce this risk.

2.2.4. User Agent State

This specification doesn’t define any additional user-agent state for an origin. However it is expected that user agents will have compilation caches for the result of expensive compilation like GPUShaderModule, GPURenderPipeline and GPUComputePipeline. These caches are important to improve the loading time of WebGPU applications after the first visit.

For the specification, these caches are indifferentiable from incredibly fast compilation, but for applications it would be easy to measure how long createComputePipelineAsync() takes to resolve. This can leak information across origins (like "did the user access a site with this specific shader") so user agents should follow the best practices in storage partitioning.

The system’s GPU driver may also have its own cache of compiled shaders and pipelines. User agents may want to disable these when at all possible, or add per-partition data to shaders in ways that will make the GPU driver consider them different.

2.2.5. Driver bugs

In addition to the concerns outlined in Security Considerations, driver bugs may introduce differences in behavior that can be observed as a method of differentiating users. The mitigations mentioned in Security Considerations apply here as well, including coordinating with GPU vendors and implementing workarounds for known issues in the user agent.

2.2.6. Adapter Identifiers

Past experience with WebGL has demonstrated that developers have a legitimate need to be able to identify the GPU their code is running on in order to create and maintain robust GPU-based content. For example, to identify adapters with known driver bugs in order to work around them or to avoid features that perform more poorly than expected on a given class of hardware.

But exposing adapter identifiers also naturally expands the amount of fingerprinting information available, so there’s a desire to limit the precision with which we identify the adapter.

There are several mitigations that can be applied to strike a balance between enabling robust content and preserving privacy. First is that user agents can reduce the burden on developers by identifying and working around known driver issues, as they have since browsers began making use of GPUs.

When adapter identifiers are exposed by default they should be as broad as possible while still being useful. Possibly identifying, for example, the adapter’s vendor and general architecture without identifying the specific adapter in use. Similarly, in some cases identifiers for an adapter that is considered a reasonable proxy for the actual adapter may be reported.

In cases where full and detailed information about the adapter is useful (for example: when filing bug reports) the user can be asked for consent to reveal additional information about their hardware to the page.

Finally, the user agent will always have the discretion to not report adapter identifiers at all if it considers it appropriate, such as in enhanced privacy modes.

3. Fundamentals

3.1. Conventions

3.1.1. Syntactic Shorthands

In this specification, the following syntactic shorthands are used:

The . ("dot") syntax, common in programming languages.

The phrasing "Foo.Bar" means "the Bar member of the value (or interface) Foo." If Foo is an ordered map and Bar does not exist in Foo, returns undefined.

The phrasing "Foo.Bar is provided" means "the Bar member exists in the map value Foo"

The ?. ("optional chaining") syntax, adopted from JavaScript.

The phrasing "Foo?.Bar" means "if Foo is null or undefined or Bar does not exist in Foo, undefined; otherwise, Foo.Bar".

For example, where buffer is a GPUBuffer, buffer?.\[[device]].\[[adapter]] means "if buffer is null or undefined, then undefined; otherwise, the \[[adapter]] internal slot of the \[[device]] internal slot of buffer.

The ?? ("nullish coalescing") syntax, adopted from JavaScript.

The phrasing "x ?? y" means "x, if x is not null or undefined, and y otherwise".

slot-backed attribute

A WebIDL attribute which is backed by an internal slot of the same name. It may or may not be mutable.

3.1.2. WebGPU Objects

A WebGPU object consists of a WebGPU Interface and an internal object.

The WebGPU interface defines the public interface and state of the WebGPU object. It can be used on the content timeline where it was created, where it is a JavaScript-exposed WebIDL interface.

Any interface which includes GPUObjectBase is a WebGPU interface.

The internal object tracks the state of the WebGPU object on the device timeline. All reads/writes to the mutable state of an internal object occur from steps executing on a single well-ordered device timeline.

The following special property types can be defined on WebGPU objects:

immutable property

A read-only slot set during initialization of the object. It can be accessed from any timeline.

Note: Since the slot is immutable, implementations may have a copy on multiple timelines, as needed. Immutable properties are defined in this way to avoid describing multiple copies in this spec.

If named [[with brackets]], it is an internal slot.
If named withoutBrackets, it is a readonly slot-backed attribute of the WebGPU interface.

content timeline property

A property which is only accessible from the content timeline where the object was created.

If named [[with brackets]], it is an internal slot.
If named withoutBrackets, it is a slot-backed attribute of the WebGPU interface.

device timeline property

A property which tracks state of the internal object and is only accessible from the device timeline where the object was created. device timeline properties may be mutable.

Device timeline properties are named [[with brackets]], and are internal slots.

queue timeline property

A property which tracks state of the internal object and is only accessible from the queue timeline where the object was created. queue timeline properties may be mutable.

Queue timeline properties are named [[with brackets]], and are internal slots.

interface mixin GPUObjectBase {
    attribute USVString label;
};
To create a new WebGPU object(GPUObjectBase parent, interface T, GPUObjectDescriptorBase descriptor) (where T extends GPUObjectBase), run the following content timeline steps:
  1. Let device be parent.[[device]].

  2. Let object be a new instance of T.

  3. Set object.[[device]] to device.

  4. Set object.label to descriptor.label.

  5. Return object.

GPUObjectBase has the following immutable properties:

[[device]], of type device, readonly

The device that owns the internal object.

Operations on the contents of this object assert they are running on the device timeline, and that the device is valid.

GPUObjectBase has the following content timeline properties:

label, of type USVString

A developer-provided label which is used in an implementation-defined way. It can be used by the browser, OS, or other tools to help identify the underlying internal object to the developer. Examples include displaying the label in GPUError messages, console warnings, browser developer tools, and platform debugging utilities.

NOTE:
Implementations should use labels to enhance error messages by using them to identify WebGPU objects.

However, this need not be the only way of identifying objects: implementations should also use other available information, especially when no label is available. For example:

NOTE:
The label is a property of the GPUObjectBase. Two GPUObjectBase "wrapper" objects have completely separate label states, even if they refer to the same underlying object (for example returned by getBindGroupLayout()). The label property will not change except by being set from JavaScript.

This means one underlying object could be associated with multiple labels. This specification does not define how the label is propagated to the device timeline. How labels are used is completely implementation-defined: error messages could show the most recently set label, all known labels, or no labels at all.

It is defined as a USVString because some user agents may supply it to the debug facilities of the underlying native APIs.

GPUObjectBase has the following device timeline properties:

[[valid]], of type boolean, initially true.

If true, indicates that the internal object is valid to use.

NOTE:
Ideally WebGPU interfaces should not prevent their parent objects, such as the [[device]] that owns them, from being garbage collected. This cannot be guaranteed, however, as holding a strong reference to a parent object may be required in some implementations.

As a result, developers should assume that a WebGPU interface may not be garbage collected until all child objects of that interface have also been garbage collected. This may cause some resources to remain allocated longer than anticipated.

Calling the destroy method on a WebGPU interface (such as GPUDevice.destroy() or GPUBuffer.destroy()) should be favored over relying on garbage collection if predictable release of allocated resources is needed.

3.1.3. Object Descriptors

An object descriptor holds the information needed to create an object, which is typically done via one of the create* methods of GPUDevice.

dictionary GPUObjectDescriptorBase {
    USVString label = "";
};

GPUObjectDescriptorBase has the following members:

label, of type USVString, defaulting to ""

The initial value of GPUObjectBase.label.

3.2. Asynchrony

3.2.1. Invalid Internal Objects & Contagious Invalidity

Object creation operations in WebGPU don’t return promises, but nonetheless are internally asynchronous. Returned objects refer to internal objects which are manipulated on a device timeline. Rather than fail with exceptions or rejections, most errors that occur on a device timeline are communicated through GPUErrors generated on the associated device.

Internal objects are either valid or invalid. An invalid object will never become valid at a later time, but some valid objects may be invalidated.

Objects are invalid from creation if it wasn’t possible to create them. This can happen, for example, if the object descriptor doesn’t describe a valid object, or if there is not enough memory to allocate a resource. It can also happen if an object is created with or from another invalid object (for example calling createView() on an invalid GPUTexture) (for example the GPUTexture of a createView() call): this case is referred to as contagious invalidity.

Internal objects of most types cannot become invalid after they are created, but still may become unusable, e.g. if the owning device is lost or destroyed, or the object has a special internal state, like buffer state "destroyed".

Internal objects of some types can become invalid after they are created; specifically, devices, adapters, GPUCommandBuffers, and command/pass/bundle encoders.

A given GPUObjectBase object is valid if object.[[valid]] is true.
A given GPUObjectBase object is invalid if object.[[valid]] is false.
A given GPUObjectBase object is valid to use with a targetObject if the all of the requirements in the following device timeline steps are met:
To invalidate a GPUObjectBase object, run the following device timeline steps:
  1. object.[[valid]] to false.

3.2.2. Promise Ordering

Several operations in WebGPU return promises.

WebGPU does not make any guarantees about the order in which these promises settle (resolve or reject), except for the following:

Applications must not rely on any other promise settlement ordering.

3.3. Coordinate Systems

Rendering operations use the following coordinate systems:

Note: WebGPU’s coordinate systems match DirectX’s coordinate systems in a graphics pipeline.

3.4. Programming Model

3.4.1. Timelines

WebGPU’s behavior is described in terms of "timelines". Each operation (defined as algorithms) occurs on a timeline. Timelines clearly define both the order of operations, and which state is available to which operations.

Note: This "timeline" model describes the constraints of the multi-process models of browser engines (typically with a "content process" and "GPU process"), as well as the GPU itself as a separate execution unit in many implementations. Implementing WebGPU does not require timelines to execute in parallel, so does not require multiple processes, or even multiple threads. (It does require concurrency for cases like get a copy of the image contents of a context which synchronously blocks on another timeline to complete.)

Content timeline

Associated with the execution of the Web script. It includes calling all methods described by this specification.

To issue steps to the content timeline from an operation on GPUDevice device, queue a global task for GPUDevice device with those steps.

Device timeline

Associated with the GPU device operations that are issued by the user agent. It includes creation of adapters, devices, and GPU resources and state objects, which are typically synchronous operations from the point of view of the user agent part that controls the GPU, but can live in a separate OS process.

Queue timeline

Associated with the execution of operations on the compute units of the GPU. It includes actual draw, copy, and compute jobs that run on the GPU.

Timeline-agnostic

Associated with any of the above timelines

Steps may be issued to any timeline if they only operate on immutable properties or arguments passed from the calling steps.

The following show the styling of steps and values associated with each timeline. This styling is non-normative; the specification text always describes the association.
Immutable value example term definition

Can be used on any timeline.

Content-timeline example term definition

Can only be used on the content timeline.

Device-timeline example term definition

Can only be used on the device timeline.

Queue-timeline example term definition

Can only be used on the queue timeline.

Steps which are timeline-agnostic look like this.

Immutable value example term usage.

Steps executed on the content timeline look like this.

Immutable value example term usage. Content-timeline example term usage.

Steps executed on the device timeline look like this.

Immutable value example term usage. Device-timeline example term usage.

Steps executed on the queue timeline look like this.

Immutable value example term usage. Queue-timeline example term usage.

In this specification, asynchronous operations are used when the return value depends on work that happens on any timeline other than the Content timeline. They are represented by promises and events in API.

GPUComputePassEncoder.dispatchWorkgroups():
  1. User encodes a dispatchWorkgroups command by calling a method of the GPUComputePassEncoder which happens on the Content timeline.

  2. User issues GPUQueue.submit() that hands over the GPUCommandBuffer to the user agent, which processes it on the Device timeline by calling the OS driver to do a low-level submission.

  3. The submit gets dispatched by the GPU invocation scheduler onto the actual compute units for execution, which happens on the Queue timeline.

GPUDevice.createBuffer():
  1. User fills out a GPUBufferDescriptor and creates a GPUBuffer with it, which happens on the Content timeline.

  2. User agent creates a low-level buffer on the Device timeline.

GPUBuffer.mapAsync():
  1. User requests to map a GPUBuffer on the Content timeline and gets a promise in return.

  2. User agent checks if the buffer is currently used by the GPU and makes a reminder to itself to check back when this usage is over.

  3. After the GPU operating on Queue timeline is done using the buffer, the user agent maps it to memory and resolves the promise.

3.4.2. Memory Model

This section is non-normative.

Once a GPUDevice has been obtained during an application initialization routine, we can describe the WebGPU platform as consisting of the following layers:

  1. User agent implementing the specification.

  2. Operating system with low-level native API drivers for this device.

  3. Actual CPU and GPU hardware.

Each layer of the WebGPU platform may have different memory types that the user agent needs to consider when implementing the specification:

Most physical resources are allocated in the memory of type that is efficient for computation or rendering by the GPU. When the user needs to provide new data to the GPU, the data may first need to cross the process boundary in order to reach the user agent part that communicates with the GPU driver. Then it may need to be made visible to the driver, which sometimes requires a copy into driver-allocated staging memory. Finally, it may need to be transferred to the dedicated GPU memory, potentially changing the internal layout into one that is most efficient for GPUs to operate on.

All of these transitions are done by the WebGPU implementation of the user agent.

Note: This example describes the worst case, while in practice the implementation may not need to cross the process boundary, or may be able to expose the driver-managed memory directly to the user behind an ArrayBuffer, thus avoiding any data copies.

3.4.3. Resource Usages

A physical resource can be used with an internal usage by a GPU command:

input

Buffer with input data for draw or dispatch calls. Preserves the contents. Allowed by buffer INDEX, buffer VERTEX, or buffer INDIRECT.

constant

Resource bindings that are constant from the shader point of view. Preserves the contents. Allowed by buffer UNIFORM or texture TEXTURE_BINDING.

storage

Read/write storage resource binding. Allowed by buffer STORAGE or texture STORAGE_BINDING.

storage-read

Read-only storage resource bindings. Preserves the contents. Allowed by buffer STORAGE or texture STORAGE_BINDING.

attachment

Texture used as a read/write output attachment or write-only resolve target in a render pass. Allowed by texture RENDER_ATTACHMENT.

attachment-read

Texture used as a read-only attachment in a render pass. Preserves the contents. Allowed by texture RENDER_ATTACHMENT.

We define subresource to be either a whole buffer, or a texture subresource.

Some internal usages are compatible with others. A subresource can be in a state that combines multiple usages together. We consider a list U to be a compatible usage list if (and only if) it satisfies any of the following rules:

Enforcing that the usages are only combined into a compatible usage list allows the API to limit when data races can occur in working with memory. That property makes applications written against WebGPU more likely to run without modification on different platforms.

EXAMPLE:
Binding the same buffer for storage as well as for input within the same GPURenderPassEncoder results in a non-compatible usage list for that buffer.
EXAMPLE:
These rules allow for read-only depth-stencil: a single depth/stencil texture can be used as two different read-only usages in a render pass simultaneously:
EXAMPLE:
The usage scope storage exception allows two cases that would not be allowed otherwise:
EXAMPLE:
The usage scope attachment exception allows a texture subresource to be used as attachment more than once. This is necessary to allow disjoint slices of 3D textures to be bound as different attachments to a single render pass.

One slice may not be bound twice for two different attachments; this is checked by beginRenderPass().

3.4.4. Synchronization

A usage scope is a map from subresource to list<internal usage>>. Each usage scope covers a range of operations which may execute in a concurrent fashion with each other, and therefore may only use subresources in consistent compatible usage lists within the scope.

A usage scope scope passes usage scope validation if, for each [subresource, usageList] in scope, usageList is a compatible usage list.
To add a subresource subresource to usage scope usageScope with usage (internal usage or set of internal usages) usage:
  1. If usageScope[subresource] does not exist, set it to [].

  2. Append usage to usageScope[subresource].

To merge usage scope A into usage scope B:
  1. For each [subresource, usage] in A:

    1. Add subresource to B with usage usage.

Usage scopes are constructed and validated during encoding:

The usage scopes are as follows:

Note: Copy commands are standalone operations and don’t use usage scopes for validation. They implement their own validation to prevent self-races.

EXAMPLE:
The following example resource usages are included in usage scopes:

3.5. Core Internal Objects

3.5.1. Adapters

An adapter identifies an implementation of WebGPU on the system: both an instance of compute/rendering functionality on the platform underlying a browser, and an instance of a browser’s implementation of WebGPU on top of that functionality.

Adapters are exposed via GPUAdapter.

Adapters do not uniquely represent underlying implementations: calling requestAdapter() multiple times returns a different adapter object each time.

Each adapter object can only be used to create one device: upon a successful requestDevice() call, the adapter’s [[state]] changes to "consumed". Additionally, adapter objects may expire at any time.

Note: This ensures applications use the latest system state for adapter selection when creating a device. It also encourages robustness to more scenarios by making them look similar: first initialization, reinitialization due to an unplugged adapter, reinitialization due to a test GPUDevice.destroy() call, etc.

An adapter may be considered a fallback adapter if it has significant performance caveats in exchange for some combination of wider compatibility, more predictable behavior, or improved privacy. It is not required that a fallback adapter is available on every system.

adapter has the following immutable properties:

[[features]], of type ordered set<GPUFeatureName>, readonly

The features which can be used to create devices on this adapter.

[[limits]], of type supported limits, readonly

The best limits which can be used to create devices on this adapter.

Each adapter limit must be the same or better than its default value in supported limits.

[[fallback]], of type boolean, readonly

If set to true indicates that the adapter is a fallback adapter.

adapter has the following device timeline properties:

[[state]], initially "valid"
"valid"

The adapter can be used to create a device.

"consumed"

The adapter has already been used to create a device, and cannot be used again.

"expired"

The adapter has expired for some other reason.

To expire a GPUAdapter adapter, run the following device timeline steps:
  1. Set adapter.[[adapter]].[[state]] to "expired".

3.5.2. Devices

A device is the logical instantiation of an adapter, through which internal objects are created.

Devices are exposed via GPUDevice.

A device is the exclusive owner of all internal objects created from it: when the device becomes invalid (is lost or destroyed), it and all objects created on it (directly, e.g. createTexture(), or indirectly, e.g. createView()) become implicitly unusable.

device has the following immutable properties:

[[adapter]], of type adapter, readonly

The adapter from which this device was created.

[[features]], of type ordered set<GPUFeatureName>, readonly

The features which can be used on this device, as computed at creation. No additional features can be used, even if the underlying adapter can support them.

[[limits]], of type supported limits, readonly

The limits which can be used on this device, as computed at creation. No better limits can be used, even if the underlying adapter can support them.

device has the following content timeline properties:

[[content device]], of type GPUDevice, readonly

The Content timeline GPUDevice interface which this device is associated with.

device has the following device timeline properties:

[[destroy started]], of type boolean, initially false

Becomes true when a destroy() operation is started, and remains true once it is finished.

Note: Once destruction starts, ongoing operations can complete and send messages back to the content timeline, but no new operations can start which do so. See also § 22 Errors & Debugging.

To create a new device from adapter adapter with GPUDeviceDescriptor descriptor, run the following device timeline steps:
  1. Let features be the set of values in descriptor.requiredFeatures.

  2. Let limits be a supported limits object with all values set to their defaults.

  3. For each (key, value) pair in descriptor.requiredLimits:

    1. If value is not undefined and value is better than limits[key]:

      1. Set limits[key] to value.

  4. Let device be a device object.

  5. Set device.[[adapter]] to adapter.

  6. Set device.[[features]] to features.

  7. Set device.[[limits]] to limits.

  8. Return device.

Any time the user agent needs to revoke access to a device, it calls lose the device(device, "unknown") on the device’s device timeline, potentially ahead of other operations currently queued on that timeline.

If an operation fails with side effects that would observably change the state of objects on the device or potentially corrupt internal implementation/driver state, the device should be lost to prevent these changes from being observable.

Note: For all device losses not initiated by the application (via destroy()), user agents should consider issuing developer-visible warnings unconditionally, even if the lost promise is handled. These scenarios should be rare, and the signal is vital to developers because most of the WebGPU API tries to behave like nothing is wrong to avoid interrupting the runtime flow of the application: no validation errors are raised, most promises resolve normally, etc.

To lose the device(device, reason) run the following device timeline steps:
  1. Invalidate device.

  2. Issue the following steps on the content timeline of device.[[content device]]:

    1. Resolve device.lost with a new GPUDeviceLostInfo with reason set to reason and message set to an implementation-defined value.

      Note: message should not disclose unnecessary user/system information and should never be parsed by applications.

  3. Complete any outstanding steps that are waiting until device becomes lost.

Note: No errors are generated from a device which is lost or pending destruction. See § 22 Errors & Debugging.

To listen for timeline event event on device device, handled by steps on timeline timeline:

Then issue steps on timeline.

3.6. Optional Capabilities

WebGPU adapters and devices have capabilities, which describe WebGPU functionality that differs between different implementations, typically due to hardware or system software constraints. A capability is either a feature or a limit.

A user agent must not reveal more than 32 distinguishable configurations or buckets.

The capabilities of an adapter must conform to § 4.2.1 Adapter Capability Guarantees.

Only supported capabilities may be requested in requestDevice(); requesting unsupported capabilities results in failure.

The capabilities of a device are determined in "a new device" by starting with the adapter’s defaults (no features and the default supported limits) and adding capabilities as requested in requestDevice(). These capabilities are enforced regardless of the capabilities of the adapter.

There is a tracking vector here. For privacy considerations, see § 2.2.1 Machine-specific features and limits.

3.6.1. Features

A feature is a set of optional WebGPU functionality that is not supported on all implementations, typically due to hardware or system software constraints.

All features are optional, but adapters make some guarantees about their availability (see § 4.2.1 Adapter Capability Guarantees).

A device supports the exact set of features determined at creation (see § 3.6 Optional Capabilities). API calls perform validation according to these features (not the adapter's features):

A GPUFeatureName feature is enabled for a GPUObjectBase object if and only if object.[[device]].[[features]] contains feature.

See the Feature Index for a description of the functionality each feature enables.

Note: Enabling features may not necessarily be desirable, as doing so may have a performance impact. Because of this, and to improve portability across devices and implementations, applications should generally only request features that they may actually require.

3.6.2. Limits

Each limit is a numeric limit on the usage of WebGPU on a device.

Note: Setting "better" limits may not necessarily be desirable, as doing so may have a performance impact. Because of this, and to improve portability across devices and implementations, applications should generally only request better limits if they may actually require them.

Each limit has a default value.

Adapters are always guaranteed to support the defaults or better (see § 4.2.1 Adapter Capability Guarantees).

A device supports the exact set of limits determined at creation (see § 3.6 Optional Capabilities). API calls perform validation according to these limits (not the adapter's limits), no better or worse.

For any given limit, some values are better than others. A better limit value always relaxes validation, enabling strictly more programs to be valid. For each limit class, "better" is defined.

Different limits have different limit classes:

maximum

The limit enforces a maximum on some value passed into the API.

Higher values are better.

May only be set to values ≥ the default. Lower values are clamped to the default.

alignment

The limit enforces a minimum alignment on some value passed into the API; that is, the value must be a multiple of the limit.

Lower values are better.

May only be set to powers of 2 which are ≤ the default. Values which are not powers of 2 are invalid. Higher powers of 2 are clamped to the default.

Note: Setting "better" limits may not necessarily be desirable, as they may have a performance impact. Because of this, and to improve portability across devices and implementations, applications should generally request the "worst" limits that work for their content (ideally, the default values).

A supported limits object has a value for every limit defined by WebGPU:

Limit name Type Limit class Default
maxTextureDimension1D GPUSize32 maximum 8192
The maximum allowed value for the size.width of a texture created with dimension "1d".
maxTextureDimension2D GPUSize32 maximum 8192
The maximum allowed value for the size.width and size.height of a texture created with dimension "2d".
maxTextureDimension3D GPUSize32 maximum 2048
The maximum allowed value for the size.width, size.height and size.depthOrArrayLayers of a texture created with dimension "3d".
maxTextureArrayLayers GPUSize32 maximum 256
The maximum allowed value for the size.depthOrArrayLayers of a texture created with dimension "2d".
maxBindGroups GPUSize32 maximum 4
The maximum number of GPUBindGroupLayouts allowed in bindGroupLayouts when creating a GPUPipelineLayout.
maxBindGroupsPlusVertexBuffers GPUSize32 maximum 24
The maximum number of bind group and vertex buffer slots used simultaneously, counting any empty slots below the highest index. Validated in createRenderPipeline() and in draw calls.
maxBindingsPerBindGroup GPUSize32 maximum 1000
The number of binding indices available when creating a GPUBindGroupLayout.

Note: This limit is normative, but arbitrary. With the default binding slot limits, it is impossible to use 1000 bindings in one bind group, but this allows GPUBindGroupLayoutEntry.binding values up to 999. This limit allows implementations to treat binding space as an array, within reasonable memory space, rather than a sparse map structure.

maxDynamicUniformBuffersPerPipelineLayout GPUSize32 maximum 8
The maximum number of GPUBindGroupLayoutEntry entries across a GPUPipelineLayout which are uniform buffers with dynamic offsets. See Exceeds the binding slot limits.
maxDynamicStorageBuffersPerPipelineLayout GPUSize32 maximum 4
The maximum number of GPUBindGroupLayoutEntry entries across a GPUPipelineLayout which are storage buffers with dynamic offsets. See Exceeds the binding slot limits.
maxSampledTexturesPerShaderStage GPUSize32 maximum 16
For each possible GPUShaderStage stage, the maximum number of GPUBindGroupLayoutEntry entries across a GPUPipelineLayout which are sampled textures. See Exceeds the binding slot limits.
maxSamplersPerShaderStage GPUSize32 maximum 16
For each possible GPUShaderStage stage, the maximum number of GPUBindGroupLayoutEntry entries across a GPUPipelineLayout which are samplers. See Exceeds the binding slot limits.
maxStorageBuffersPerShaderStage GPUSize32 maximum 8
For each possible GPUShaderStage stage, the maximum number of GPUBindGroupLayoutEntry entries across a GPUPipelineLayout which are storage buffers. See Exceeds the binding slot limits.
maxStorageTexturesPerShaderStage GPUSize32 maximum 4
For each possible GPUShaderStage stage, the maximum number of GPUBindGroupLayoutEntry entries across a GPUPipelineLayout which are storage textures. See Exceeds the binding slot limits.
maxUniformBuffersPerShaderStage GPUSize32 maximum 12
For each possible GPUShaderStage stage, the maximum number of GPUBindGroupLayoutEntry entries across a GPUPipelineLayout which are uniform buffers. See Exceeds the binding slot limits.
maxUniformBufferBindingSize GPUSize64 maximum 65536 bytes
The maximum GPUBufferBinding.size for bindings with a GPUBindGroupLayoutEntry entry for which entry.buffer?.type is "uniform".
maxStorageBufferBindingSize GPUSize64 maximum 134217728 bytes (128 MiB)
The maximum GPUBufferBinding.size for bindings with a GPUBindGroupLayoutEntry entry for which entry.buffer?.type is "storage" or "read-only-storage".
minUniformBufferOffsetAlignment GPUSize32 alignment 256 bytes
The required alignment for GPUBufferBinding.offset and the dynamic offsets provided in setBindGroup(), for bindings with a GPUBindGroupLayoutEntry entry for which entry.buffer?.type is "uniform".
minStorageBufferOffsetAlignment GPUSize32 alignment 256 bytes
The required alignment for GPUBufferBinding.offset and the dynamic offsets provided in setBindGroup(), for bindings with a GPUBindGroupLayoutEntry entry for which entry.buffer?.type is "storage" or "read-only-storage".
maxVertexBuffers GPUSize32 maximum 8
The maximum number of buffers when creating a GPURenderPipeline.
maxBufferSize GPUSize64 maximum 268435456 bytes (256 MiB)
The maximum size of size when creating a GPUBuffer.
maxVertexAttributes GPUSize32 maximum 16
The maximum number of attributes in total across buffers when creating a GPURenderPipeline.
maxVertexBufferArrayStride GPUSize32 maximum 2048 bytes
The maximum allowed arrayStride when creating a GPURenderPipeline.
maxInterStageShaderVariables GPUSize32 maximum 16
The maximum allowed number of input or output variables for inter-stage communication (like vertex outputs or fragment inputs).
maxColorAttachments GPUSize32 maximum 8
The maximum allowed number of color attachments in GPURenderPipelineDescriptor.fragment.targets, GPURenderPassDescriptor.colorAttachments, and GPURenderPassLayout.colorFormats.
maxColorAttachmentBytesPerSample GPUSize32 maximum 32
The maximum number of bytes necessary to hold one sample (pixel or subpixel) of render pipeline output data, across all color attachments.
maxComputeWorkgroupStorageSize GPUSize32 maximum 16384 bytes
The maximum number of bytes of workgroup storage used for a compute stage GPUShaderModule entry-point.
maxComputeInvocationsPerWorkgroup GPUSize32 maximum 256
The maximum value of the product of the workgroup_size dimensions for a compute stage GPUShaderModule entry-point.
maxComputeWorkgroupSizeX GPUSize32 maximum 256
The maximum value of the workgroup_size X dimension for a compute stage GPUShaderModule entry-point.
maxComputeWorkgroupSizeY GPUSize32 maximum 256
The maximum value of the workgroup_size Y dimensions for a compute stage GPUShaderModule entry-point.
maxComputeWorkgroupSizeZ GPUSize32 maximum 64
The maximum value of the workgroup_size Z dimensions for a compute stage GPUShaderModule entry-point.
maxComputeWorkgroupsPerDimension GPUSize32 maximum 65535
The maximum value for the arguments of dispatchWorkgroups(workgroupCountX, workgroupCountY, workgroupCountZ).
3.6.2.1. GPUSupportedLimits

GPUSupportedLimits exposes an adapter or device’s supported limits. See GPUAdapter.limits and GPUDevice.limits.

[Exposed=(Window, Worker), SecureContext]
interface GPUSupportedLimits {
    readonly attribute unsigned long maxTextureDimension1D;
    readonly attribute unsigned long maxTextureDimension2D;
    readonly attribute unsigned long maxTextureDimension3D;
    readonly attribute unsigned long maxTextureArrayLayers;
    readonly attribute unsigned long maxBindGroups;
    readonly attribute unsigned long maxBindGroupsPlusVertexBuffers;
    readonly attribute unsigned long maxBindingsPerBindGroup;
    readonly attribute unsigned long maxDynamicUniformBuffersPerPipelineLayout;
    readonly attribute unsigned long maxDynamicStorageBuffersPerPipelineLayout;
    readonly attribute unsigned long maxSampledTexturesPerShaderStage;
    readonly attribute unsigned long maxSamplersPerShaderStage;
    readonly attribute unsigned long maxStorageBuffersPerShaderStage;
    readonly attribute unsigned long maxStorageTexturesPerShaderStage;
    readonly attribute unsigned long maxUniformBuffersPerShaderStage;
    readonly attribute unsigned long long maxUniformBufferBindingSize;
    readonly attribute unsigned long long maxStorageBufferBindingSize;
    readonly attribute unsigned long minUniformBufferOffsetAlignment;
    readonly attribute unsigned long minStorageBufferOffsetAlignment;
    readonly attribute unsigned long maxVertexBuffers;
    readonly attribute unsigned long long maxBufferSize;
    readonly attribute unsigned long maxVertexAttributes;
    readonly attribute unsigned long maxVertexBufferArrayStride;
    readonly attribute unsigned long maxInterStageShaderVariables;
    readonly attribute unsigned long maxColorAttachments;
    readonly attribute unsigned long maxColorAttachmentBytesPerSample;
    readonly attribute unsigned long maxComputeWorkgroupStorageSize;
    readonly attribute unsigned long maxComputeInvocationsPerWorkgroup;
    readonly attribute unsigned long maxComputeWorkgroupSizeX;
    readonly attribute unsigned long maxComputeWorkgroupSizeY;
    readonly attribute unsigned long maxComputeWorkgroupSizeZ;
    readonly attribute unsigned long maxComputeWorkgroupsPerDimension;
};
3.6.2.2. GPUSupportedFeatures

GPUSupportedFeatures is a setlike interface. Its set entries are the GPUFeatureName values of the features supported by an adapter or device. It must only contain strings from the GPUFeatureName enum.

[Exposed=(Window, Worker), SecureContext]
interface GPUSupportedFeatures {
    readonly setlike<DOMString>;
};
NOTE:
The type of the GPUSupportedFeatures set entries is DOMString to allow user agents to gracefully handle valid GPUFeatureNames which are added in later revisions of the spec but which the user agent has not been updated to recognize yet. If the set entries type was GPUFeatureName the following code would throw an TypeError rather than reporting false:
Check for support of an unrecognized feature:
if (adapter.features.has('unknown-feature')) {
    // Use unknown-feature
} else {
    console.warn('unknown-feature is not supported by this adapter.');
}
3.6.2.3. WGSLLanguageFeatures

WGSLLanguageFeatures is the setlike interface of navigator.gpu.wgslLanguageFeatures. Its set entries are the string names of the WGSL language extensions supported by the implementation (regardless of the adapter or device).

[Exposed=(Window, Worker), SecureContext]
interface WGSLLanguageFeatures {
    readonly setlike<DOMString>;
};
3.6.2.4. GPUAdapterInfo

GPUAdapterInfo exposes various identifying information about an adapter.

None of the members in GPUAdapterInfo are guaranteed to be populated with any particular value; if no value is provided, the attribute will return the empty string "". It is at the user agent’s discretion which values to reveal, and it is likely that on some devices none of the values will be populated. As such, applications must be able to handle any possible GPUAdapterInfo values, including the absence of those values.

The information exposed by a GPUAdapter is immutable: for a given adapter, each GPUAdapterInfo attribute will return the same value every time it’s accessed.

Note: Though the GPUAdapterInfo attributes are immutable once accessed, an implementation may delay the decision on what to expose for each attribute until the first time it is accessed.

Note: Other GPUAdapter instances, even if they represent the same physical adapter, may expose different values in GPUAdapterInfo. However, they should expose the same values unless a specific event has increased the amount of identifying information the page is allowed to access. (No such events are defined by this specification.)

There is a tracking vector here. For privacy considerations, see § 2.2.6 Adapter Identifiers.

[Exposed=(Window, Worker), SecureContext]
interface GPUAdapterInfo {
    readonly attribute DOMString vendor;
    readonly attribute DOMString architecture;
    readonly attribute DOMString device;
    readonly attribute DOMString description;
};

GPUAdapterInfo has the following attributes:

vendor, of type DOMString, readonly

The name of the vendor of the adapter, if available. Empty string otherwise.

architecture, of type DOMString, readonly

The name of the family or class of GPUs the adapter belongs to, if available. Empty string otherwise.

device, of type DOMString, readonly

A vendor-specific identifier for the adapter, if available. Empty string otherwise.

Note: This is a value that represents the type of adapter. For example, it may be a PCI device ID. It does not uniquely identify a given piece of hardware like a serial number.

description, of type DOMString, readonly

A human readable string describing the adapter as reported by the driver, if available. Empty string otherwise.

Note: Because no formatting is applied to description attempting to parse this value is not recommended. Applications which change their behavior based on the GPUAdapterInfo, such as applying workarounds for known driver issues, should rely on the other fields when possible.

To create a new adapter info for a given adapter adapter, run the following content timeline steps:
  1. Let adapterInfo be a new GPUAdapterInfo.

  2. If the vendor is known, set adapterInfo.vendor to the name of adapter’s vendor as a normalized identifier string. To preserve privacy, the user agent may instead set adapterInfo.vendor to the empty string or a reasonable approximation of the vendor as a normalized identifier string.

  3. If |the architecture is known, set adapterInfo.architecture to a normalized identifier string representing the family or class of adapters to which adapter belongs. To preserve privacy, the user agent may instead set adapterInfo.architecture to the empty string or a reasonable approximation of the architecture as a normalized identifier string.

  4. If the device is known, set adapterInfo.device to a normalized identifier string representing a vendor-specific identifier for adapter. To preserve privacy, the user agent may instead set adapterInfo.device to to the empty string or a reasonable approximation of a vendor-specific identifier as a normalized identifier string.

  5. If a description is known, set adapterInfo.description to a description of the adapter as reported by the driver. To preserve privacy, the user agent may instead set adapterInfo.description to the empty string or a reasonable approximation of a description.

  6. Return adapterInfo.

A normalized identifier string is one that follows the following pattern:

[a-z0-9]+(-[a-z0-9]+)*

a-z 0-9 -
Examples of valid normalized identifier strings include:
  • gpu

  • 3d

  • 0x3b2f

  • next-gen

  • series-x20-ultra

3.7. Extension Documents

"Extension Documents" are additional documents which describe new functionality which is non-normative and not part of the WebGPU/WGSL specifications. They describe functionality that builds upon these specifications, often including one or more new API feature flags and/or WGSL enable directives, or interactions with other draft web specifications.

WebGPU implementations must not expose extension functionality; doing so is a spec violation. New functionality does not become part of the WebGPU standard until it is integrated into the WebGPU specification (this document) and/or WGSL specification.

3.8. Origin Restrictions

WebGPU allows accessing image data stored in images, videos, and canvases. Restrictions are imposed on the use of cross-domain media, because shaders can be used to indirectly deduce the contents of textures which have been uploaded to the GPU.

WebGPU disallows uploading an image source if it is not origin-clean.

This also implies that the origin-clean flag for a canvas rendered using WebGPU will never be set to false.

For more information on issuing CORS requests for image and video elements, consult:

3.9. Task Sources

3.9.1. WebGPU Task Source

WebGPU defines a new task source called the WebGPU task source. It is used for the uncapturederror event and GPUDevice.lost.

To queue a global task for GPUDevice device, with a series of steps steps on the content timeline:
  1. Queue a global task on the WebGPU task source, with the global object that was used to create device, and the steps steps.

3.9.2. Automatic Expiry Task Source

WebGPU defines a new task source called the automatic expiry task source. It is used for the automatic, timed expiry (destruction) of certain objects:

To queue an automatic expiry task with GPUDevice device and a series of steps steps on the content timeline:
  1. Queue a global task on the automatic expiry task source, with the global object that was used to create device, and the steps steps.

Tasks from the automatic expiry task source should be processed with high priority; in particular, once queued, they should run before user-defined (JavaScript) tasks.

NOTE:
This behavior is more predictable, and the strictness helps developers write more portable applications by eagerly detecting incorrect assumptions about implicit lifetimes that may be hard to detect. Developers are still strongly encouraged to test in multiple implementations.

Implementation note: It is valid to implement a high-priority expiry "task" by instead inserting additional steps at a fixed point inside the event loop processing model rather than running an actual task.

3.10. Color Spaces and Encoding

WebGPU does not provide color management. All values within WebGPU (such as texture elements) are raw numeric values, not color-managed color values.

WebGPU does interface with color-managed outputs (via GPUCanvasConfiguration) and inputs (via copyExternalImageToTexture() and importExternalTexture()). Thus, color conversion must be performed between the WebGPU numeric values and the external color values. Each such interface point locally defines an encoding (color space, transfer function, and alpha premultiplication) in which the WebGPU numeric values are to be interpreted.

WebGPU allows all of the color spaces in the PredefinedColorSpace enum. Note, each color space is defined over an extended range, as defined by the referenced CSS definitions, to represent color values outside of its space (in both chrominance and luminance).

An out-of-gamut premultiplied RGBA value is one where any of the R/G/B channel values exceeds the alpha channel value. For example, the premultiplied sRGB RGBA value [1.0, 0, 0, 0.5] represents the (unpremultiplied) color [2, 0, 0] with 50% alpha, written rgb(srgb 2 0 0 / 50%) in CSS. Just like any color value outside the sRGB color gamut, this is a well defined point in the extended color space (except when alpha is 0, in which case there is no color). However, when such values are output to a visible canvas, the result is undefined (see GPUCanvasAlphaMode "premultiplied").

3.10.1. Color Space Conversions

A color is converted between spaces by translating its representation in one space to a representation in another according to the definitions above.

If the source value has fewer than 4 RGBA channels, the missing green/blue/alpha channels are set to 0, 0, 1, respectively, before converting for color space/encoding and alpha premultiplication. After conversion, if the destination needs fewer than 4 channels, the additional channels are ignored.

Note: Grayscale images generally represent RGB values (V, V, V), or RGBA values (V, V, V, A) in their color space.

Colors are not lossily clamped during conversion: converting from one color space to another will result in values outside the range [0, 1] if the source color values were outside the range of the destination color space’s gamut. For an sRGB destination, for example, this can occur if the source is rgba16float, in a wider color space like Display-P3, or is premultiplied and contains out-of-gamut values.

Similarly, if the source value has a high bit depth (e.g. PNG with 16 bits per component) or extended range (e.g. canvas with float16 storage), these colors are preserved through color space conversion, with intermediate computations having at least the precision of the source.

3.10.2. Color Space Conversion Elision

If the source and destination of a color space/encoding conversion are the same, then conversion is not necessary. In general, if any given step of the conversion is an identity function (no-op), implementations should elide it, for performance.

For optimal performance, applications should set their color space and encoding options so that the number of necessary conversions is minimized throughout the process. For various image sources of GPUCopyExternalImageSourceInfo:

Note: Check browser implementation support for these features before relying on them.

3.11. Numeric conversions from JavaScript to WGSL

Several parts of the WebGPU API (pipeline-overridable constants and render pass clear values) take numeric values from WebIDL (double or float) and convert them to WGSL values (bool, i32, u32, f32, f16).

To convert an IDL value idlValue of type double or float to WGSL type T, possibly throwing a TypeError, run the following device timeline steps:

Note: This TypeError is generated in the device timeline and never surfaced to JavaScript.

  1. Assert idlValue is a finite value, since it is not unrestricted double or unrestricted float.

  2. Let v be the ECMAScript Number resulting from ! converting idlValue to an ECMAScript value.

  3. If T is bool

    Return the WGSL bool value corresponding to the result of ! converting v to an IDL value of type boolean.

    Note: This algorithm is called after the conversion from an ECMAScript value to an IDL double or float value. If the original ECMAScript value was a non-numeric, non-boolean value like [] or {}, then the WGSL bool result may be different than if the ECMAScript value had been converted to IDL boolean directly.

    If T is i32

    Return the WGSL i32 value corresponding to the result of ? converting v to an IDL value of type [EnforceRange] long.

    If T is u32

    Return the WGSL u32 value corresponding to the result of ? converting v to an IDL value of type [EnforceRange] unsigned long.

    If T is f32

    Return the WGSL f32 value corresponding to the result of ? converting v to an IDL value of type float.

    If T is f16
    1. Let wgslF32 be the WGSL f32 value corresponding to the result of ? converting v to an IDL value of type float.

    2. Return f16(wgslF32), the result of ! converting the WGSL f32 value to f16 as defined in WGSL floating point conversion.

    Note: As long as the value is in-range of f32, no error is thrown, even if the value is out-of-range of f16.

To convert a GPUColor color to a texel value of texture format format, possibly throwing a TypeError, run the following device timeline steps:

Note: This TypeError is generated in the device timeline and never surfaced to JavaScript.

  1. If the components of format (assert they all have the same type) are:

    floating-point types or normalized types

    Let T be f32.

    signed integer types

    Let T be i32.

    unsigned integer types

    Let T be u32.

  2. Let wgslColor be a WGSL value of type vec4<T>, where the 4 components are the RGBA channels of color, each ? converted to WGSL type T.

  3. Convert wgslColor to format using the same conversion rules as the § 23.2.7 Output Merging step, and return the result.

    Note: For non-integer types, the exact choice of value is implementation-defined. For normalized types, the value is clamped to the range of the type.

Note: In other words, the value written will be as if it was written by a WGSL shader that outputs the value represented as a vec4 of f32, i32, or u32.

4. Initialization

A GPU object is available in the Window and WorkerGlobalScope contexts through the Navigator and WorkerNavigator interfaces respectively and is exposed via navigator.gpu:

interface mixin NavigatorGPU {
    [SameObject, SecureContext] readonly attribute GPU gpu;
};
Navigator includes NavigatorGPU;
WorkerNavigator includes NavigatorGPU;

NavigatorGPU has the following attributes:

gpu, of type GPU, readonly

A global singleton providing top-level entry points like requestAdapter().

4.2. GPU

GPU is the entry point to WebGPU.

[Exposed=(Window, Worker), SecureContext]
interface GPU {
    Promise<GPUAdapter?> requestAdapter(optional GPURequestAdapterOptions options = {});
    GPUTextureFormat getPreferredCanvasFormat();
    [SameObject] readonly attribute WGSLLanguageFeatures wgslLanguageFeatures;
};

GPU has the following methods:

requestAdapter(options)

Requests an adapter from the user agent. The user agent chooses whether to return an adapter, and, if so, chooses according to the provided options.

Called on: GPU this.

Arguments:

Arguments for the GPU.requestAdapter(options) method.
Parameter Type Nullable Optional Description
options GPURequestAdapterOptions Criteria used to select the adapter.

Returns: Promise<GPUAdapter?>

Content timeline steps:

  1. Let contentTimeline be the current Content timeline.

  2. Let promise be a new promise.

  3. Issue the initialization steps on the Device timeline of this.

  4. Return promise.

Device timeline initialization steps:
  1. All of the requirements in the following steps must be met.

    1. options.featureLevel must be a feature level string.

    If they are met and the user agent chooses to return an adapter:

    1. Set adapter to an adapter chosen according to the rules in § 4.2.2 Adapter Selection and the criteria in options, adhering to § 4.2.1 Adapter Capability Guarantees.

      The supported limits of the adapter must adhere to the requirements defined in § 3.6.2 Limits.

    2. If adapter meets the criteria of a fallback adapter set adapter.[[fallback]] to true.

    Otherwise:

    1. Let adapter be null.

  2. Issue the subsequent steps on contentTimeline.

Content timeline steps:
  1. If adapter is not null:

    1. Resolve promise with a new GPUAdapter encapsulating adapter.

  2. Otherwise, Resolve promise with null.

getPreferredCanvasFormat()

Returns an optimal GPUTextureFormat for displaying 8-bit depth, standard dynamic range content on this system. Must only return "rgba8unorm" or "bgra8unorm".

The returned value can be passed as the format to configure() calls on a GPUCanvasContext to ensure the associated canvas is able to display its contents efficiently.

Note: Canvases which are not displayed to the screen may or may not benefit from using this format.

Called on: GPU this.

Returns: GPUTextureFormat

Content timeline steps:

  1. Return either "rgba8unorm" or "bgra8unorm", depending on which format is optimal for displaying WebGPU canvases on this system.

GPU has the following attributes:

wgslLanguageFeatures, of type WGSLLanguageFeatures, readonly

The names of supported WGSL language extensions. Supported language extensions are automatically enabled.

Adapters may expire at any time. Upon any change in the system’s state that could affect the result of any requestAdapter() call, the user agent should expire all previously-returned adapters. For example:

Note: User agents may choose to expire adapters often, even when there has been no system state change (e.g. seconds or minutes after the adapter was created). This can help obfuscate real system state changes, and make developers more aware that calling requestAdapter() again is always necessary before calling requestDevice(). If an application does encounter this situation, standard device-loss recovery handling should allow it to recover.

Requesting a GPUAdapter with no hints:
const gpuAdapter = await navigator.gpu.requestAdapter();

4.2.1. Adapter Capability Guarantees

Any GPUAdapter returned by requestAdapter() must provide the following guarantees:

4.2.2. Adapter Selection

GPURequestAdapterOptions provides hints to the user agent indicating what configuration is suitable for the application.

dictionary GPURequestAdapterOptions {
    DOMString featureLevel = "core";
    GPUPowerPreference powerPreference;
    boolean forceFallbackAdapter = false;
};
enum GPUPowerPreference {
    "low-power",
    "high-performance",
};

GPURequestAdapterOptions has the following members:

featureLevel, of type DOMString, defaulting to "core"

"Feature level" for the adapter request.

The allowed feature level string values are:

"core"

No effect.

"compatibility"

No effect.

Note: This value is reserved for future use as a way to opt into additional validation restrictions. Applications should not use this value at this time.

powerPreference, of type GPUPowerPreference

Optionally provides a hint indicating what class of adapter should be selected from the system’s available adapters.

The value of this hint may influence which adapter is chosen, but it must not influence whether an adapter is returned or not.

Note: The primary utility of this hint is to influence which GPU is used in a multi-GPU system. For instance, some laptops have a low-power integrated GPU and a high-performance discrete GPU. This hint may also affect the power configuration of the selected GPU to match the requested power preference.

Note: Depending on the exact hardware configuration, such as battery status and attached displays or removable GPUs, the user agent may select different adapters given the same power preference. Typically, given the same hardware configuration and state and powerPreference, the user agent is likely to select the same adapter.

It must be one of the following values:

undefined (or not present)

Provides no hint to the user agent.

"low-power"

Indicates a request to prioritize power savings over performance.

Note: Generally, content should use this if it is unlikely to be constrained by drawing performance; for example, if it renders only one frame per second, draws only relatively simple geometry with simple shaders, or uses a small HTML canvas element. Developers are encouraged to use this value if their content allows, since it may significantly improve battery life on portable devices.

"high-performance"

Indicates a request to prioritize performance over power consumption.

Note: By choosing this value, developers should be aware that, for devices created on the resulting adapter, user agents are more likely to force device loss, in order to save power by switching to a lower-power adapter. Developers are encouraged to only specify this value if they believe it is absolutely necessary, since it may significantly decrease battery life on portable devices.

forceFallbackAdapter, of type boolean, defaulting to false

When set to true indicates that only a fallback adapter may be returned. If the user agent does not support a fallback adapter, will cause requestAdapter() to resolve to null.

Note: requestAdapter() may still return a fallback adapter if forceFallbackAdapter is set to false and either no other appropriate adapter is available or the user agent chooses to return a fallback adapter. Developers that wish to prevent their applications from running on fallback adapters should check the GPUAdapter.isFallbackAdapter attribute prior to requesting a GPUDevice.

Requesting a "high-performance" GPUAdapter:
const gpuAdapter = await navigator.gpu.requestAdapter({
    powerPreference: 'high-performance'
});

4.3. GPUAdapter

A GPUAdapter encapsulates an adapter, and describes its capabilities (features and limits).

To get a GPUAdapter, use requestAdapter().

[Exposed=(Window, Worker), SecureContext]
interface GPUAdapter {
    [SameObject] readonly attribute GPUSupportedFeatures features;
    [SameObject] readonly attribute GPUSupportedLimits limits;
    [SameObject] readonly attribute GPUAdapterInfo info;
    readonly attribute boolean isFallbackAdapter;

    Promise<GPUDevice> requestDevice(optional GPUDeviceDescriptor descriptor = {});
};

GPUAdapter has the following immutable properties

features, of type GPUSupportedFeatures, readonly

The set of values in this.[[adapter]].[[features]].

limits, of type GPUSupportedLimits, readonly

The limits in this.[[adapter]].[[limits]].

info, of type GPUAdapterInfo, readonly

Information about the physical adapter underlying this GPUAdapter.

For a given GPUAdapter, the GPUAdapterInfo values exposed are constant over time.

The same object is returned each time. To create that object for the first time:

Called on: GPUAdapter this.

Returns: GPUAdapterInfo

Content timeline steps:

  1. Return a new adapter info for this.[[adapter]].

isFallbackAdapter, of type boolean, readonly

Returns the value of [[adapter]].[[fallback]].

[[adapter]], of type adapter, readonly

The adapter to which this GPUAdapter refers.

GPUAdapter has the following methods:

requestDevice(descriptor)

Requests a device from the adapter.

This is a one-time action: if a device is returned successfully, the adapter becomes "consumed".

Called on: GPUAdapter this.

Arguments:

Arguments for the GPUAdapter.requestDevice(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUDeviceDescriptor Description of the GPUDevice to request.

Returns: Promise<GPUDevice>

Content timeline steps:

  1. Let contentTimeline be the current Content timeline.

  2. Let promise be a new promise.

  3. Let adapter be this.[[adapter]].

  4. Issue the initialization steps to the Device timeline of this.

  5. Return promise.

Device timeline initialization steps:
  1. If any of the following requirements are unmet:

    Then issue the following steps on contentTimeline and return:

    Content timeline steps:
    1. Reject promise with a TypeError.

    Note: This is the same error that is produced if a feature name isn’t known by the browser at all (in its GPUFeatureName definition). This converges the behavior when the browser doesn’t support a feature with the behavior when a particular adapter doesn’t support a feature.

  2. All of the requirements in the following steps must be met.

    1. adapter.[[state]] must not be "consumed".

    2. For each [key, value] in descriptor.requiredLimits for which value is not undefined:

      1. key must be the name of a member of supported limits.

      2. value must be no better than adapter.[[limits]][key].

      3. If key’s class is alignment, value must be a power of 2 less than 232.

      Note: User agents should consider issuing developer-visible warnings when key is not recognized, even when value is undefined.

    If any are unmet, issue the following steps on contentTimeline and return:

    Content timeline steps:
    1. Reject promise with an OperationError.

  3. If adapter.[[state]] is "expired" or the user agent otherwise cannot fulfill the request:

    1. Let device be a new device.

    2. Lose the device(device, "unknown").

    3. Assert adapter.[[state]] is "expired".

      Note: User agents should consider issuing developer-visible warnings in most or all cases when this occurs. Applications should perform reinitialization logic starting with requestAdapter().

    Otherwise:

    1. Let device be a new device with the capabilities described by descriptor.

    2. Expire adapter.

  4. Issue the subsequent steps on contentTimeline.

Content timeline steps:
  1. Let gpuDevice be a new GPUDevice instance.

  2. Set gpuDevice.[[device]] to device.

  3. Set device.[[content device]] to gpuDevice.

  4. Set gpuDevice.label to descriptor.label.

  5. Resolve promise with gpuDevice.

    Note: If the device is already lost because the adapter could not fulfill the request, device.lost has already resolved before promise resolves.

Requesting a GPUDevice with default features and limits:
const gpuAdapter = await navigator.gpu.requestAdapter();
const gpuDevice = await gpuAdapter.requestDevice();

4.3.1. GPUDeviceDescriptor

GPUDeviceDescriptor describes a device request.

dictionary GPUDeviceDescriptor
         : GPUObjectDescriptorBase {
    sequence<GPUFeatureName> requiredFeatures = [];
    record<DOMString, (GPUSize64 or undefined)> requiredLimits = {};
    GPUQueueDescriptor defaultQueue = {};
};

GPUDeviceDescriptor has the following members:

requiredFeatures, of type sequence<GPUFeatureName>, defaulting to []

Specifies the features that are required by the device request. The request will fail if the adapter cannot provide these features.

Exactly the specified set of features, and no more or less, will be allowed in validation of API calls on the resulting device.

requiredLimits, of type record<DOMString, (GPUSize64 or undefined)>, defaulting to {}

Specifies the limits that are required by the device request. The request will fail if the adapter cannot provide these limits.

Each key with a non-undefined value must be the name of a member of supported limits.

API calls on the resulting device perform validation according to the exact limits of the device (not the adapter; see § 3.6.2 Limits).

defaultQueue, of type GPUQueueDescriptor, defaulting to {}

The descriptor for the default GPUQueue.

Requesting a GPUDevice with the "texture-compression-astc" feature if supported:
const gpuAdapter = await navigator.gpu.requestAdapter();

const requiredFeatures = [];
if (gpuAdapter.features.has('texture-compression-astc')) {
    requiredFeatures.push('texture-compression-astc')
}

const gpuDevice = await gpuAdapter.requestDevice({
    requiredFeatures
});
Requesting a GPUDevice with a higher maxColorAttachmentBytesPerSample limit:
const gpuAdapter = await navigator.gpu.requestAdapter();

if (gpuAdapter.limits.maxColorAttachmentBytesPerSample < 64) {
    // When the desired limit isn’t supported, take action to either fall back to a code
    // path that does not require the higher limit or notify the user that their device
    // does not meet minimum requirements.
}

// Request higher limit of max color attachments bytes per sample.
const gpuDevice = await gpuAdapter.requestDevice({
    requiredLimits: { maxColorAttachmentBytesPerSample: 64 },
});
4.3.1.1. GPUFeatureName

Each GPUFeatureName identifies a set of functionality which, if available, allows additional usages of WebGPU that would have otherwise been invalid.

enum GPUFeatureName {
    "depth-clip-control",
    "depth32float-stencil8",
    "texture-compression-bc",
    "texture-compression-bc-sliced-3d",
    "texture-compression-etc2",
    "texture-compression-astc",
    "texture-compression-astc-sliced-3d",
    "timestamp-query",
    "indirect-first-instance",
    "shader-f16",
    "rg11b10ufloat-renderable",
    "bgra8unorm-storage",
    "float32-filterable",
    "float32-blendable",
    "clip-distances",
    "dual-source-blending",
};

4.4. GPUDevice

A GPUDevice encapsulates a device and exposes the functionality of that device.

GPUDevice is the top-level interface through which WebGPU interfaces are created.

To get a GPUDevice, use requestDevice().

[Exposed=(Window, Worker), SecureContext]
interface GPUDevice : EventTarget {
    [SameObject] readonly attribute GPUSupportedFeatures features;
    [SameObject] readonly attribute GPUSupportedLimits limits;

    [SameObject] readonly attribute GPUQueue queue;

    undefined destroy();

    GPUBuffer createBuffer(GPUBufferDescriptor descriptor);
    GPUTexture createTexture(GPUTextureDescriptor descriptor);
    GPUSampler createSampler(optional GPUSamplerDescriptor descriptor = {});
    GPUExternalTexture importExternalTexture(GPUExternalTextureDescriptor descriptor);

    GPUBindGroupLayout createBindGroupLayout(GPUBindGroupLayoutDescriptor descriptor);
    GPUPipelineLayout createPipelineLayout(GPUPipelineLayoutDescriptor descriptor);
    GPUBindGroup createBindGroup(GPUBindGroupDescriptor descriptor);

    GPUShaderModule createShaderModule(GPUShaderModuleDescriptor descriptor);
    GPUComputePipeline createComputePipeline(GPUComputePipelineDescriptor descriptor);
    GPURenderPipeline createRenderPipeline(GPURenderPipelineDescriptor descriptor);
    Promise<GPUComputePipeline> createComputePipelineAsync(GPUComputePipelineDescriptor descriptor);
    Promise<GPURenderPipeline> createRenderPipelineAsync(GPURenderPipelineDescriptor descriptor);

    GPUCommandEncoder createCommandEncoder(optional GPUCommandEncoderDescriptor descriptor = {});
    GPURenderBundleEncoder createRenderBundleEncoder(GPURenderBundleEncoderDescriptor descriptor);

    GPUQuerySet createQuerySet(GPUQuerySetDescriptor descriptor);
};
GPUDevice includes GPUObjectBase;

GPUDevice has the following immutable properties:

features, of type GPUSupportedFeatures, readonly

A set containing the GPUFeatureName values of the features supported by the device ([[device]].[[features]]).

limits, of type GPUSupportedLimits, readonly

The limits supported by the device ([[device]].[[limits]]).

queue, of type GPUQueue, readonly

The primary GPUQueue for this device.

The [[device]] for a GPUDevice is the device that the GPUDevice refers to.

GPUDevice has the following methods:

destroy()

Destroys the device, preventing further operations on it. Outstanding asynchronous operations will fail.

Note: It is valid to destroy a device multiple times.

Called on: GPUDevice this.

Content timeline steps:

  1. unmap() all GPUBuffers from this device.

  2. Issue the subsequent steps on the Device timeline of this.

Device timeline steps:
  1. Set this.[[device]].[[destroy started]] to true.

  2. Once:

    • All currently-enqueued operations on any queue on this device have completed, and

    • Any device timeline steps that were listening for completion of queue operations have completed (asserting that no new listeners were added after [[destroy started]] was set):

    Then issue the subsequent steps on the current timeline.

  1. Lose the device(this.[[device]], "destroyed").

Note: Since no further operations can be enqueued on this device, implementations can abort outstanding asynchronous operations immediately and free resource allocations, including mapped memory that was just unmapped.

A GPUDevice's allowed buffer usages are:
A GPUDevice's allowed texture usages are:

4.5. Example

A more robust example of requesting a GPUAdapter and GPUDevice with error handling:
let gpuDevice = null;

async function initializeWebGPU() {
    // Check to ensure the user agent supports WebGPU.
    if (!('gpu' in navigator)) {
        console.error("User agent doesn’t support WebGPU.");
        return false;
    }

    // Request an adapter.
    const gpuAdapter = await navigator.gpu.requestAdapter();

    // requestAdapter may resolve with null if no suitable adapters are found.
    if (!gpuAdapter) {
        console.error('No WebGPU adapters found.');
        return false;
    }

    // Request a device.
    // Note that the promise will reject if invalid options are passed to the optional
    // dictionary. To avoid the promise rejecting always check any features and limits
    // against the adapters features and limits prior to calling requestDevice().
    gpuDevice = await gpuAdapter.requestDevice();

    // requestDevice will never return null, but if a valid device request can’t be
    // fulfilled for some reason it may resolve to a device which has already been lost.
    // Additionally, devices can be lost at any time after creation for a variety of reasons
    // (ie: browser resource management, driver updates), so it’s a good idea to always
    // handle lost devices gracefully.
    gpuDevice.lost.then((info) => {
        console.error(`WebGPU device was lost: ${info.message}`);

        gpuDevice = null;

        // Many causes for lost devices are transient, so applications should try getting a
        // new device once a previous one has been lost unless the loss was caused by the
        // application intentionally destroying the device. Note that any WebGPU resources
        // created with the previous device (buffers, textures, etc) will need to be
        // re-created with the new one.
        if (info.reason != 'destroyed') {
            initializeWebGPU();
        }
    });

    onWebGPUInitialized();

    return true;
}

function onWebGPUInitialized() {
    // Begin creating WebGPU resources here...
}

initializeWebGPU();

5. Buffers

5.1. GPUBuffer

A GPUBuffer represents a block of memory that can be used in GPU operations. Data is stored in linear layout, meaning that each byte of the allocation can be addressed by its offset from the start of the GPUBuffer, subject to alignment restrictions depending on the operation. Some GPUBuffers can be mapped which makes the block of memory accessible via an ArrayBuffer called its mapping.

GPUBuffers are created via createBuffer(). Buffers may be mappedAtCreation.

[Exposed=(Window, Worker), SecureContext]
interface GPUBuffer {
    readonly attribute GPUSize64Out size;
    readonly attribute GPUFlagsConstant usage;

    readonly attribute GPUBufferMapState mapState;

    Promise<undefined> mapAsync(GPUMapModeFlags mode, optional GPUSize64 offset = 0, optional GPUSize64 size);
    ArrayBuffer getMappedRange(optional GPUSize64 offset = 0, optional GPUSize64 size);
    undefined unmap();

    undefined destroy();
};
GPUBuffer includes GPUObjectBase;

enum GPUBufferMapState {
    "unmapped",
    "pending",
    "mapped",
};

GPUBuffer has the following immutable properties:

size, of type GPUSize64Out, readonly

The length of the GPUBuffer allocation in bytes.

usage, of type GPUFlagsConstant, readonly

The allowed usages for this GPUBuffer.

GPUBuffer has the following content timeline properties:

mapState, of type GPUBufferMapState, readonly

The current GPUBufferMapState of the buffer:

"unmapped"

The buffer is not mapped for use by this.getMappedRange().

"pending"

A mapping of the buffer has been requested, but is pending. It may succeed, or fail validation in mapAsync().

"mapped"

The buffer is mapped and this.getMappedRange() may be used.

The getter steps are:

Content timeline steps:
  1. If this.[[mapping]] is not null, return "mapped".

  2. If this.[[pending_map]] is not null, return "pending".

  3. Return "unmapped".

[[pending_map]], of type Promise<void> or null, initially null

The Promise returned by the currently-pending mapAsync() call.

There is never more than one pending map, because mapAsync() will refuse immediately if a request is already in flight.

[[mapping]], of type active buffer mapping or null, initially null

Set if and only if the buffer is currently mapped for use by getMappedRange(). Null otherwise (even if there is a [[pending_map]]).

An active buffer mapping is a structure with the following fields:

data, of type Data Block

The mapping for this GPUBuffer. This data is accessed through ArrayBuffers which are views onto this data, returned by getMappedRange() and stored in views.

mode, of type GPUMapModeFlags

The GPUMapModeFlags of the map, as specified in the corresponding call to mapAsync() or createBuffer().

range, of type tuple [unsigned long long, unsigned long long]

The range of this GPUBuffer that is mapped.

views, of type list<ArrayBuffer>

The ArrayBuffers returned via getMappedRange() to the application. They are tracked so they can be detached when unmap() is called.

To initialize an active buffer mapping with mode mode and range range, run the following content timeline steps:
  1. Let size be range[1] - range[0].

  2. Let data be ? CreateByteDataBlock(size).

    NOTE:
    This may result in a RangeError being thrown. For consistency and predictability:
    • For any size at which new ArrayBuffer() would succeed at a given moment, this allocation should succeed at that moment.

    • For any size at which new ArrayBuffer() deterministically throws a RangeError, this allocation should as well.

  3. Return an active buffer mapping with:

Mapping and unmapping a buffer.
Failing to map a buffer.

GPUBuffer has the following device timeline properties:

[[internal state]]

The current internal state of the buffer:

"available"

The buffer may be used in queue operations (unless it is invalid).

"unavailable"

The buffer may not be used in queue operations due to being mapped.

"destroyed"

The buffer may not be used in any operations due to being destroy()ed.

5.1.1. GPUBufferDescriptor

dictionary GPUBufferDescriptor
         : GPUObjectDescriptorBase {
    required GPUSize64 size;
    required GPUBufferUsageFlags usage;
    boolean mappedAtCreation = false;
};

GPUBufferDescriptor has the following members:

size, of type GPUSize64

The size of the buffer in bytes.

usage, of type GPUBufferUsageFlags

The allowed usages for the buffer.

mappedAtCreation, of type boolean, defaulting to false

If true creates the buffer in an already mapped state, allowing getMappedRange() to be called immediately. It is valid to set mappedAtCreation to true even if usage does not contain MAP_READ or MAP_WRITE. This can be used to set the buffer’s initial data.

Guarantees that even if the buffer creation eventually fails, it will still appear as if the mapped range can be written/read to until it is unmapped.

5.1.2. Buffer Usages

typedef [EnforceRange] unsigned long GPUBufferUsageFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUBufferUsage {
    const GPUFlagsConstant MAP_READ      = 0x0001;
    const GPUFlagsConstant MAP_WRITE     = 0x0002;
    const GPUFlagsConstant COPY_SRC      = 0x0004;
    const GPUFlagsConstant COPY_DST      = 0x0008;
    const GPUFlagsConstant INDEX         = 0x0010;
    const GPUFlagsConstant VERTEX        = 0x0020;
    const GPUFlagsConstant UNIFORM       = 0x0040;
    const GPUFlagsConstant STORAGE       = 0x0080;
    const GPUFlagsConstant INDIRECT      = 0x0100;
    const GPUFlagsConstant QUERY_RESOLVE = 0x0200;
};

The GPUBufferUsage flags determine how a GPUBuffer may be used after its creation:

MAP_READ

The buffer can be mapped for reading. (Example: calling mapAsync() with GPUMapMode.READ)

May only be combined with COPY_DST.

MAP_WRITE

The buffer can be mapped for writing. (Example: calling mapAsync() with GPUMapMode.WRITE)

May only be combined with COPY_SRC.

COPY_SRC

The buffer can be used as the source of a copy operation. (Examples: as the source argument of a copyBufferToBuffer() or copyBufferToTexture() call.)

COPY_DST

The buffer can be used as the destination of a copy or write operation. (Examples: as the destination argument of a copyBufferToBuffer() or copyTextureToBuffer() call, or as the target of a writeBuffer() call.)

INDEX

The buffer can be used as an index buffer. (Example: passed to setIndexBuffer().)

VERTEX

The buffer can be used as a vertex buffer. (Example: passed to setVertexBuffer().)

UNIFORM

The buffer can be used as a uniform buffer. (Example: as a bind group entry for a GPUBufferBindingLayout with a buffer.type of "uniform".)

STORAGE

The buffer can be used as a storage buffer. (Example: as a bind group entry for a GPUBufferBindingLayout with a buffer.type of "storage" or "read-only-storage".)

INDIRECT

The buffer can be used as to store indirect command arguments. (Examples: as the indirectBuffer argument of a drawIndirect() or dispatchWorkgroupsIndirect() call.)

QUERY_RESOLVE

The buffer can be used to capture query results. (Example: as the destination argument of a resolveQuerySet() call.)

5.1.3. Buffer Creation

createBuffer(descriptor)

Creates a GPUBuffer.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createBuffer(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUBufferDescriptor Description of the GPUBuffer to create.

Returns: GPUBuffer

Content timeline steps:

  1. Let b be ! create a new WebGPU object(this, GPUBuffer, descriptor).

  2. Set b.size to descriptor.size.

  3. Set b.usage to descriptor.usage.

  4. If descriptor.mappedAtCreation is true:

    1. Set b.[[mapping]] to ? initialize an active buffer mapping with mode WRITE and range [0, descriptor.size].

  5. Issue the initialization steps on the Device timeline of this.

  6. Return b.

Device timeline initialization steps:
  1. If any of the following requirements are unmet, generate a validation error, invalidate b and return.

Note: If buffer creation fails, and descriptor.mappedAtCreation is false, any calls to mapAsync() will reject, so any resources allocated to enable mapping can and may be discarded or recycled.

  1. If descriptor.mappedAtCreation is true:

    1. Set b.[[internal state]] to "unavailable".

    Else:

    1. Set b.[[internal state]] to "available".

  2. Create a device allocation for b where each byte is zero.

    If the allocation fails without side-effects, generate an out-of-memory error, invalidate b, and return.

Creating a 128 byte uniform buffer that can be written into:
const buffer = gpuDevice.createBuffer({
    size: 128,
    usage: GPUBufferUsage.UNIFORM | GPUBufferUsage.COPY_DST
});

5.1.4. Buffer Destruction

An application that no longer requires a GPUBuffer can choose to lose access to it before garbage collection by calling destroy(). Destroying a buffer also unmaps it, freeing any memory allocated for the mapping.

Note: This allows the user agent to reclaim the GPU memory associated with the GPUBuffer once all previously submitted operations using it are complete.

GPUBuffer has the following methods:

destroy()

Destroys the GPUBuffer.

Note: It is valid to destroy a buffer multiple times.

Called on: GPUBuffer this.

Returns: undefined

Content timeline steps:

  1. Call this.unmap().

  2. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Set this.[[internal state]] to "destroyed".

Note: Since no further operations can be enqueued using this buffer, implementations can free resource allocations, including mapped memory that was just unmapped.

5.2. Buffer Mapping

An application can request to map a GPUBuffer so that they can access its content via ArrayBuffers that represent part of the GPUBuffer's allocations. Mapping a GPUBuffer is requested asynchronously with mapAsync() so that the user agent can ensure the GPU finished using the GPUBuffer before the application can access its content. A mapped GPUBuffer cannot be used by the GPU and must be unmapped using unmap() before work using it can be submitted to the Queue timeline.

Once the GPUBuffer is mapped, the application can synchronously ask for access to ranges of its content with getMappedRange(). The returned ArrayBuffer can only be detached by unmap() (directly, or via GPUBuffer.destroy() or GPUDevice.destroy()), and cannot be transferred. A TypeError is thrown by any other operation that attempts to do so.

typedef [EnforceRange] unsigned long GPUMapModeFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUMapMode {
    const GPUFlagsConstant READ  = 0x0001;
    const GPUFlagsConstant WRITE = 0x0002;
};

The GPUMapMode flags determine how a GPUBuffer is mapped when calling mapAsync():

READ

Only valid with buffers created with the MAP_READ usage.

Once the buffer is mapped, calls to getMappedRange() will return an ArrayBuffer containing the buffer’s current values. Changes to the returned ArrayBuffer will be discarded after unmap() is called.

WRITE

Only valid with buffers created with the MAP_WRITE usage.

Once the buffer is mapped, calls to getMappedRange() will return an ArrayBuffer containing the buffer’s current values. Changes to the returned ArrayBuffer will be stored in the GPUBuffer after unmap() is called.

Note: Since the MAP_WRITE buffer usage may only be combined with the COPY_SRC buffer usage, mapping for writing can never return values produced by the GPU, and the returned ArrayBuffer will only ever contain the default initialized data (zeros) or data written by the webpage during a previous mapping.

GPUBuffer has the following methods:

mapAsync(mode, offset, size)

Maps the given range of the GPUBuffer and resolves the returned Promise when the GPUBuffer's content is ready to be accessed with getMappedRange().

The resolution of the returned Promise only indicates that the buffer has been mapped. It does not guarantee the completion of any other operations visible to the content timeline, and in particular does not imply that any other Promise returned from onSubmittedWorkDone() or mapAsync() on other GPUBuffers have resolved.

The resolution of the Promise returned from onSubmittedWorkDone() does imply the completion of mapAsync() calls made prior to that call, on GPUBuffers last used exclusively on that queue.

Called on: GPUBuffer this.

Arguments:

Arguments for the GPUBuffer.mapAsync(mode, offset, size) method.
Parameter Type Nullable Optional Description
mode GPUMapModeFlags Whether the buffer should be mapped for reading or writing.
offset GPUSize64 Offset in bytes into the buffer to the start of the range to map.
size GPUSize64 Size in bytes of the range to map.

Returns: Promise<undefined>

Content timeline steps:

  1. Let contentTimeline be the current Content timeline.

  2. If this.mapState is not "unmapped":

    1. Issue the early-reject steps on the Device timeline of this.[[device]].

    2. Return a promise rejected with OperationError.

  3. Let p be a new Promise.

  4. Set this.[[pending_map]] to p.

  5. Issue the validation steps on the Device timeline of this.[[device]].

  6. Return p.

Device timeline early-reject steps:
  1. Generate a validation error.

  2. Return.

Device timeline validation steps:
  1. If size is undefined:

    1. Let rangeSize be max(0, this.size - offset).

    Otherwise:

    1. Let rangeSize be size.

  2. If any of the following conditions are unsatisfied:

    Then:

    1. Issue the map failure steps on contentTimeline.

    2. Generate a validation error.

    3. Return.

  3. Set this.[[internal state]] to "unavailable".

    Note: Since the buffer is mapped, its contents cannot change between this step and unmap().

  4. If this.[[device]].[[destroy started]] is true:

    1. Return.

    Note: The map promise will already have been aborted, because GPUDevice.destroy() aborts it, so there is no need to do so here.

  5. When either of the following events occur (whichever comes first), or if either has already occurred:

    • The device timeline becomes informed of the completion of an unspecified queue timeline point:

      • after the completion of currently-enqueued operations that use this

      • and no later than the completion of all currently-enqueued operations (regardless of whether they use this).

    • this.[[device]] becomes lost.

    Then issue the subsequent steps on the device timeline of this.[[device]].

Device timeline steps:
  1. Set deviceLost to true if this.[[device]] is lost, and false otherwise.

  2. If deviceLost:

    1. Issue the map failure steps on contentTimeline.

    Otherwise:

    1. Let internalStateAtCompletion be this.[[internal state]].

      Note: If, and only if, at this point the buffer has become "available" again due to an unmap() call, then [[pending_map]] != p below, so mapping will not succeed in the steps below.

    2. Let dataForMappedRegion be the contents of this starting at offset offset, for rangeSize bytes.

    3. Issue the map success steps on the contentTimeline.

Content timeline map success steps:
  1. If this.[[pending_map]] != p:

    Note: The map has been cancelled by unmap().

    1. Assert p is rejected.

    2. Return.

  2. Assert p is pending.

  3. Assert internalStateAtCompletion is "unavailable".

  4. Let mapping be initialize an active buffer mapping with mode mode and range [offset, offset + rangeSize].

    If this allocation fails:

    1. Set this.[[pending_map]] to null, and reject p with a RangeError.

    2. Return.

  5. Set the content of mapping.data to dataForMappedRegion.

  6. Set this.[[mapping]] to mapping.

  7. Set this.[[pending_map]] to null, and resolve p.

Content timeline map failure steps:
  1. If this.[[pending_map]] != p:

    Note: The map has been cancelled by unmap().

    1. Assert p is already rejected.

    2. Return.

  2. Assert p is still pending.

  3. Set this.[[pending_map]] to null.

  4. If deviceLost:

    1. Reject p with an AbortError.

      Note: This is the same error type produced by cancelling the map using unmap().

    Otherwise:

    1. Reject p with an OperationError.

getMappedRange(offset, size)

Returns an ArrayBuffer with the contents of the GPUBuffer in the given mapped range.

Called on: GPUBuffer this.

Arguments:

Arguments for the GPUBuffer.getMappedRange(offset, size) method.
Parameter Type Nullable Optional Description
offset GPUSize64 Offset in bytes into the buffer to return buffer contents from.
size GPUSize64 Size in bytes of the ArrayBuffer to return.

Returns: ArrayBuffer

Content timeline steps:

  1. If size is missing:

    1. Let rangeSize be max(0, this.size - offset).

    Otherwise, let rangeSize be size.

  2. If any of the following conditions are unsatisfied, throw an OperationError and return.

    Note: It is always valid to get mapped ranges of a GPUBuffer that is mappedAtCreation, even if it is invalid, because the Content timeline might not know it is invalid.

  3. Let data be this.[[mapping]].data.

  4. Let view be ! create an ArrayBuffer of size rangeSize, but with its pointer mutably referencing the content of data at offset (offset - [[mapping]].range[0]).

    Note: A RangeError may not be thrown here, because the data has already been allocated during mapAsync() or createBuffer().

  5. Set view.[[ArrayBufferDetachKey]] to "WebGPUBufferMapping".

    Note: This causes a TypeError to be thrown if an attempt is made to DetachArrayBuffer, except by unmap().

  6. Append view to this.[[mapping]].views.

  7. Return view.

Note: User agents should consider issuing a developer-visible warning if getMappedRange() succeeds without having checked the status of the map, by waiting for mapAsync() to succeed, querying a mapState of "mapped", or waiting for a later onSubmittedWorkDone() call to succeed.

unmap()

Unmaps the mapped range of the GPUBuffer and makes its contents available for use by the GPU again.

Called on: GPUBuffer this.

Returns: undefined

Content timeline steps:

  1. If this.[[pending_map]] is not null:

    1. Reject this.[[pending_map]] with an AbortError.

    2. Set this.[[pending_map]] to null.

  2. If this.[[mapping]] is null:

    1. Return.

  3. For each ArrayBuffer ab in this.[[mapping]].views:

    1. Perform DetachArrayBuffer(ab, "WebGPUBufferMapping").

  4. Let bufferUpdate be null.

  5. If this.[[mapping]].mode contains WRITE:

    1. Set bufferUpdate to { data: this.[[mapping]].data, offset: this.[[mapping]].range[0] }.

    Note: When a buffer is mapped without the WRITE mode, then unmapped, any local modifications done by the application to the mapped ranges ArrayBuffer are discarded and will not affect the content of later mappings.

  6. Set this.[[mapping]] to null.

  7. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. If any of the following conditions are unsatisfied, return.

  2. Assert this.[[internal state]] is "unavailable".

  3. If bufferUpdate is not null:

    1. Issue the following steps on the Queue timeline of this.[[device]].queue:

      Queue timeline steps:
      1. Update the contents of this at offset bufferUpdate.offset with the data bufferUpdate.data.

  4. Set this.[[internal state]] to "available".

6. Textures and Texture Views

6.1. GPUTexture

A texture is made up of 1d, 2d, or 3d arrays of data which can contain multiple values per-element to represent things like colors. Textures can be read and written in many ways, depending on the GPUTextureUsage they are created with. For example, textures can be sampled, read, and written from render and compute pipeline shaders, and they can be written by render pass outputs. Internally, textures are often stored in GPU memory with a layout optimized for multidimensional access rather than linear access.

One texture consists of one or more texture subresources, each uniquely identified by a mipmap level and, for 2d textures only, array layer and aspect.

A texture subresource is a subresource: each can be used in different internal usages within a single usage scope.

Each subresource in a mipmap level is approximately half the size, in each spatial dimension, of the corresponding resource in the lesser level (see logical miplevel-specific texture extent). The subresource in level 0 has the dimensions of the texture itself. Smaller levels are typically used to store lower resolution versions of the same image. GPUSampler and WGSL provide facilities for selecting and interpolating between levels of detail, explicitly or automatically.

A "2d" texture may be an array of array layers. Each subresource in a layer is the same size as the corresponding resources in other layers. For non-2d textures, all subresources have an array layer index of 0.

Each subresource has an aspect. Color textures have just one aspect: color. Depth-or-stencil format textures may have multiple aspects: a depth aspect, a stencil aspect, or both, and may be used in special ways, such as in depthStencilAttachment and in "depth" bindings.

A "3d" texture may have multiple slices, each being the two-dimensional image at a particular z value in the texture. Slices are not separate subresources.

[Exposed=(Window, Worker), SecureContext]
interface GPUTexture {
    GPUTextureView createView(optional GPUTextureViewDescriptor descriptor = {});

    undefined destroy();

    readonly attribute GPUIntegerCoordinateOut width;
    readonly attribute GPUIntegerCoordinateOut height;
    readonly attribute GPUIntegerCoordinateOut depthOrArrayLayers;
    readonly attribute GPUIntegerCoordinateOut mipLevelCount;
    readonly attribute GPUSize32Out sampleCount;
    readonly attribute GPUTextureDimension dimension;
    readonly attribute GPUTextureFormat format;
    readonly attribute GPUFlagsConstant usage;
};
GPUTexture includes GPUObjectBase;

GPUTexture has the following immutable properties:

width, of type GPUIntegerCoordinateOut, readonly

The width of this GPUTexture.

height, of type GPUIntegerCoordinateOut, readonly

The height of this GPUTexture.

depthOrArrayLayers, of type GPUIntegerCoordinateOut, readonly

The depth or layer count of this GPUTexture.

mipLevelCount, of type GPUIntegerCoordinateOut, readonly

The number of mip levels of this GPUTexture.

sampleCount, of type GPUSize32Out, readonly

The number of sample count of this GPUTexture.

dimension, of type GPUTextureDimension, readonly

The dimension of the set of texel for each of this GPUTexture's subresources.

format, of type GPUTextureFormat, readonly

The format of this GPUTexture.

usage, of type GPUFlagsConstant, readonly

The allowed usages for this GPUTexture.

[[viewFormats]], of type sequence<GPUTextureFormat>

The set of GPUTextureFormats that can be used as the GPUTextureViewDescriptor.format when creating views on this GPUTexture.

GPUTexture has the following device timeline properties:

[[destroyed]], of type boolean, initially false

If the texture is destroyed, it can no longer be used in any operation, and its underlying memory can be freed.

compute render extent(baseSize, mipLevel)

Arguments:

Returns: GPUExtent3DDict

Device timeline steps:

  1. Let extent be a new GPUExtent3DDict object.

  2. Set extent.width to max(1, baseSize.widthmipLevel).

  3. Set extent.height to max(1, baseSize.heightmipLevel).

  4. Set extent.depthOrArrayLayers to 1.

  5. Return extent.

The logical miplevel-specific texture extent of a texture is the size of the texture in texels at a specific miplevel. It is calculated by this procedure:

Logical miplevel-specific texture extent(descriptor, mipLevel)

Arguments:

Returns: GPUExtent3DDict

  1. Let extent be a new GPUExtent3DDict object.

  2. If descriptor.dimension is:

    "1d"
    "2d"
    "3d"
  3. Return extent.

The physical miplevel-specific texture extent of a texture is the size of the texture in texels at a specific miplevel that includes the possible extra padding to form complete texel blocks in the texture. It is calculated by this procedure:

Physical miplevel-specific texture extent(descriptor, mipLevel)

Arguments:

Returns: GPUExtent3DDict

  1. Let extent be a new GPUExtent3DDict object.

  2. Let logicalExtent be logical miplevel-specific texture extent(descriptor, mipLevel).

  3. If descriptor.dimension is:

    "1d"
    "2d"
    "3d"
  4. Return extent.

6.1.1. GPUTextureDescriptor

dictionary GPUTextureDescriptor
         : GPUObjectDescriptorBase {
    required GPUExtent3D size;
    GPUIntegerCoordinate mipLevelCount = 1;
    GPUSize32 sampleCount = 1;
    GPUTextureDimension dimension = "2d";
    required GPUTextureFormat format;
    required GPUTextureUsageFlags usage;
    sequence<GPUTextureFormat> viewFormats = [];
};

GPUTextureDescriptor has the following members:

size, of type GPUExtent3D

The width, height, and depth or layer count of the texture.

mipLevelCount, of type GPUIntegerCoordinate, defaulting to 1

The number of mip levels the texture will contain.

sampleCount, of type GPUSize32, defaulting to 1

The sample count of the texture. A sampleCount > 1 indicates a multisampled texture.

dimension, of type GPUTextureDimension, defaulting to "2d"

Whether the texture is one-dimensional, an array of two-dimensional layers, or three-dimensional.

format, of type GPUTextureFormat

The format of the texture.

usage, of type GPUTextureUsageFlags

The allowed usages for the texture.

viewFormats, of type sequence<GPUTextureFormat>, defaulting to []

Specifies what view format values will be allowed when calling createView() on this texture (in addition to the texture’s actual format).

NOTE:
Adding a format to this list may have a significant performance impact, so it is best to avoid adding formats unnecessarily.

The actual performance impact is highly dependent on the target system; developers must test various systems to find out the impact on their particular application. For example, on some systems any texture with a format or viewFormats entry including "rgba8unorm-srgb" will perform less optimally than a "rgba8unorm" texture which does not. Similar caveats exist for other formats and pairs of formats on other systems.

Formats in this list must be texture view format compatible with the texture format.

Two GPUTextureFormats format and viewFormat are texture view format compatible if:
  • format equals viewFormat, or

  • format and viewFormat differ only in whether they are srgb formats (have the -srgb suffix).

enum GPUTextureDimension {
    "1d",
    "2d",
    "3d",
};
"1d"

Specifies a texture that has one dimension, width. "1d" textures cannot have mipmaps, be multisampled, use compressed or depth/stencil formats, or be used as a render target.

"2d"

Specifies a texture that has a width and height, and may have layers.

"3d"

Specifies a texture that has a width, height, and depth. "3d" textures cannot be multisampled, and their format must support 3d textures (all plain color formats and some packed/compressed formats).

6.1.2. Texture Usages

typedef [EnforceRange] unsigned long GPUTextureUsageFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUTextureUsage {
    const GPUFlagsConstant COPY_SRC          = 0x01;
    const GPUFlagsConstant COPY_DST          = 0x02;
    const GPUFlagsConstant TEXTURE_BINDING   = 0x04;
    const GPUFlagsConstant STORAGE_BINDING   = 0x08;
    const GPUFlagsConstant RENDER_ATTACHMENT = 0x10;
};

The GPUTextureUsage flags determine how a GPUTexture may be used after its creation:

COPY_SRC

The texture can be used as the source of a copy operation. (Examples: as the source argument of a copyTextureToTexture() or copyTextureToBuffer() call.)

COPY_DST

The texture can be used as the destination of a copy or write operation. (Examples: as the destination argument of a copyTextureToTexture() or copyBufferToTexture() call, or as the target of a writeTexture() call.)

TEXTURE_BINDING

The texture can be bound for use as a sampled texture in a shader (Example: as a bind group entry for a GPUTextureBindingLayout.)

STORAGE_BINDING

The texture can be bound for use as a storage texture in a shader (Example: as a bind group entry for a GPUStorageTextureBindingLayout.)

RENDER_ATTACHMENT

The texture can be used as a color or depth/stencil attachment in a render pass. (Example: as a GPURenderPassColorAttachment.view or GPURenderPassDepthStencilAttachment.view.)

maximum mipLevel count(dimension, size)

Arguments:

  1. Calculate the max dimension value m:

  2. Return floor(log2(m)) + 1.

6.1.3. Texture Creation

createTexture(descriptor)

Creates a GPUTexture.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createTexture(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUTextureDescriptor Description of the GPUTexture to create.

Returns: GPUTexture

Content timeline steps:

  1. ? validate GPUExtent3D shape(descriptor.size).

  2. ? Validate texture format required features of descriptor.format with this.[[device]].

  3. ? Validate texture format required features of each element of descriptor.viewFormats with this.[[device]].

  4. Let t be ! create a new WebGPU object(this, GPUTexture, descriptor).

  5. Set t.width to descriptor.size.width.

  6. Set t.height to descriptor.size.height.

  7. Set t.depthOrArrayLayers to descriptor.size.depthOrArrayLayers.

  8. Set t.mipLevelCount to descriptor.mipLevelCount.

  9. Set t.sampleCount to descriptor.sampleCount.

  10. Set t.dimension to descriptor.dimension.

  11. Set t.format to descriptor.format.

  12. Set t.usage to descriptor.usage.

  13. Issue the initialization steps on the Device timeline of this.

  14. Return t.

Device timeline initialization steps:
  1. If any of the following conditions are unsatisfied generate a validation error, invalidate t and return.

  2. Set t.[[viewFormats]] to descriptor.viewFormats.

  3. Create a device allocation for t where each block has an equivalent texel representation to a block with a bit representation of zero.

    If the allocation fails without side-effects, generate an out-of-memory error, invalidate t, and return.

validating GPUTextureDescriptor(this, descriptor):

Arguments:

Device timeline steps:

  1. Return true if all of the following requirements are met, and false otherwise:

Creating a 16x16, RGBA, 2D texture with one array layer and one mip level:
const texture = gpuDevice.createTexture({
    size: { width: 16, height: 16 },
    format: 'rgba8unorm',
    usage: GPUTextureUsage.TEXTURE_BINDING,
});

6.1.4. Texture Destruction

An application that no longer requires a GPUTexture can choose to lose access to it before garbage collection by calling destroy().

Note: This allows the user agent to reclaim the GPU memory associated with the GPUTexture once all previously submitted operations using it are complete.

GPUTexture has the following methods:

destroy()

Destroys the GPUTexture.

Called on: GPUTexture this.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the device timeline.

Device timeline steps:
  1. Set this.[[destroyed]] to true.

6.2. GPUTextureView

A GPUTextureView is a view onto some subset of the texture subresources defined by a particular GPUTexture.

[Exposed=(Window, Worker), SecureContext]
interface GPUTextureView {
};
GPUTextureView includes GPUObjectBase;

GPUTextureView has the following immutable properties:

[[texture]], readonly

The GPUTexture into which this is a view.

[[descriptor]], readonly

The GPUTextureViewDescriptor describing this texture view.

All optional fields of GPUTextureViewDescriptor are defined.

[[renderExtent]], readonly

For renderable views, this is the effective GPUExtent3DDict for rendering.

Note: this extent depends on the baseMipLevel.

The set of subresources of a texture view view, with [[descriptor]] desc, is the subset of the subresources of view.[[texture]] for which each subresource s satisfies the following:

Two GPUTextureView objects are texture-view-aliasing if and only if their sets of subresources intersect.

6.2.1. Texture View Creation

dictionary GPUTextureViewDescriptor
         : GPUObjectDescriptorBase {
    GPUTextureFormat format;
    GPUTextureViewDimension dimension;
    GPUTextureUsageFlags usage = 0;
    GPUTextureAspect aspect = "all";
    GPUIntegerCoordinate baseMipLevel = 0;
    GPUIntegerCoordinate mipLevelCount;
    GPUIntegerCoordinate baseArrayLayer = 0;
    GPUIntegerCoordinate arrayLayerCount;
};

GPUTextureViewDescriptor has the following members:

format, of type GPUTextureFormat

The format of the texture view. Must be either the format of the texture or one of the viewFormats specified during its creation.

dimension, of type GPUTextureViewDimension

The dimension to view the texture as.

usage, of type GPUTextureUsageFlags, defaulting to 0

The allowed usage(s) for the texture view. Must be a subset of the usage flags of the texture. If 0, defaults to the full set of usage flags of the texture.

Note: If the view’s format doesn’t support all of the texture’s usages, the default will fail, and the view’s usage must be specified explicitly.

aspect, of type GPUTextureAspect, defaulting to "all"

Which aspect(s) of the texture are accessible to the texture view.

baseMipLevel, of type GPUIntegerCoordinate, defaulting to 0

The first (most detailed) mipmap level accessible to the texture view.

mipLevelCount, of type GPUIntegerCoordinate

How many mipmap levels, starting with baseMipLevel, are accessible to the texture view.

baseArrayLayer, of type GPUIntegerCoordinate, defaulting to 0

The index of the first array layer accessible to the texture view.

arrayLayerCount, of type GPUIntegerCoordinate

How many array layers, starting with baseArrayLayer, are accessible to the texture view.

enum GPUTextureViewDimension {
    "1d",
    "2d",
    "2d-array",
    "cube",
    "cube-array",
    "3d",
};
"1d"

The texture is viewed as a 1-dimensional image.

Corresponding WGSL types:

  • texture_1d

  • texture_storage_1d

"2d"

The texture is viewed as a single 2-dimensional image.

Corresponding WGSL types:

  • texture_2d

  • texture_storage_2d

  • texture_multisampled_2d

  • texture_depth_2d

  • texture_depth_multisampled_2d

"2d-array"

The texture view is viewed as an array of 2-dimensional images.

Corresponding WGSL types:

  • texture_2d_array

  • texture_storage_2d_array

  • texture_depth_2d_array

"cube"

The texture is viewed as a cubemap.

The view has 6 array layers, each corresponding to a face of the cube in the order [+X, -X, +Y, -Y, +Z, -Z] and the following orientations:

Cubemap faces. The +U/+V axes indicate the individual faces' texture coordinates, and thus the texel copy memory layout of each face.

Note: When viewed from the inside, this results in a left-handed coordinate system where +X is right, +Y is up, and +Z is forward.

Sampling is done seamlessly across the faces of the cubemap.

Corresponding WGSL types:

  • texture_cube

  • texture_depth_cube

"cube-array"

The texture is viewed as a packed array of n cubemaps, each with 6 array layers behaving like one "cube" view, for 6n array layers in total.

Corresponding WGSL types:

  • texture_cube_array

  • texture_depth_cube_array

"3d"

The texture is viewed as a 3-dimensional image.

Corresponding WGSL types:

  • texture_3d

  • texture_storage_3d

Each GPUTextureAspect value corresponds to a set of aspects. The set of aspects are defined for each value below.

enum GPUTextureAspect {
    "all",
    "stencil-only",
    "depth-only",
};
"all"

All available aspects of the texture format will be accessible to the texture view. For color formats the color aspect will be accessible. For combined depth-stencil formats both the depth and stencil aspects will be accessible. Depth-or-stencil formats with a single aspect will only make that aspect accessible.

The set of aspects is [color, depth, stencil].

"stencil-only"

Only the stencil aspect of a depth-or-stencil format format will be accessible to the texture view.

The set of aspects is [stencil].

"depth-only"

Only the depth aspect of a depth-or-stencil format format will be accessible to the texture view.

The set of aspects is [depth].

createView(descriptor)

Creates a GPUTextureView.

NOTE:
By default createView() will create a view with a dimension that can represent the entire texture. For example, calling createView() without specifying a dimension on a "2d" texture with more than one layer will create a "2d-array" GPUTextureView, even if an arrayLayerCount of 1 is specified.

For textures created from sources where the layer count is unknown at the time of development it is recommended that calls to createView() are provided with an explicit dimension to ensure shader compatibility.

Called on: GPUTexture this.

Arguments:

Arguments for the GPUTexture.createView(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUTextureViewDescriptor Description of the GPUTextureView to create.

Returns: view, of type GPUTextureView.

Content timeline steps:

  1. ? Validate texture format required features of descriptor.format with this.[[device]].

  2. Let view be ! create a new WebGPU object(this, GPUTextureView, descriptor).

  3. Issue the initialization steps on the Device timeline of this.

  4. Return view.

Device timeline initialization steps:
  1. Set descriptor to the result of resolving GPUTextureViewDescriptor defaults for this with descriptor.

  2. If any of the following conditions are unsatisfied generate a validation error, invalidate view and return.

  3. Let view be a new GPUTextureView object.

  4. Set view.[[texture]] to this.

  5. Set view.[[descriptor]] to descriptor.

  6. If descriptor.usage contains RENDER_ATTACHMENT:

    1. Let renderExtent be compute render extent([this.width, this.height, this.depthOrArrayLayers], descriptor.baseMipLevel).

    2. Set view.[[renderExtent]] to renderExtent.

When resolving GPUTextureViewDescriptor defaults for GPUTextureView texture with a GPUTextureViewDescriptor descriptor, run the following device timeline steps:
  1. Let resolved be a copy of descriptor.

  2. If resolved.format is not provided:

    1. Let format be the result of resolving GPUTextureAspect( format, descriptor.aspect).

    2. If format is null:

      Otherwise:

      • Set resolved.format to format.

  3. If resolved.mipLevelCount is not provided: set resolved.mipLevelCount to texture.mipLevelCountresolved.baseMipLevel.

  4. If resolved.dimension is not provided and texture.dimension is:

    "1d"

    Set resolved.dimension to "1d".

    "2d"

    If the array layer count of texture is 1:

    Otherwise:

    "3d"

    Set resolved.dimension to "3d".

  5. If resolved.arrayLayerCount is not provided and resolved.dimension is:

    "1d", "2d", or "3d"

    Set resolved.arrayLayerCount to 1.

    "cube"

    Set resolved.arrayLayerCount to 6.

    "2d-array" or "cube-array"

    Set resolved.arrayLayerCount to the array layer count of textureresolved.baseArrayLayer.

  6. If resolved.usage is 0: set resolved.usage to texture.usage.

  7. Return resolved.

To determine the array layer count of GPUTexture texture, run the following steps:
  1. If texture.dimension is:

    "1d" or "3d"

    Return 1.

    "2d"

    Return texture.depthOrArrayLayers.

6.3. Texture Formats

The name of the format specifies the order of components, bits per component, and data type for the component.

If the format has the -srgb suffix, then sRGB conversions from gamma to linear and vice versa are applied during the reading and writing of color values in the shader. Compressed texture formats are provided by features. Their naming should follow the convention here, with the texture name as a prefix. e.g. etc2-rgba8unorm.

The texel block is a single addressable element of the textures in pixel-based GPUTextureFormats, and a single compressed block of the textures in block-based compressed GPUTextureFormats.

The texel block width and texel block height specifies the dimension of one texel block.

The texel block copy footprint of an aspect of a GPUTextureFormat is the number of bytes one texel block occupies during a texel copy, if applicable.

Note: The texel block memory cost of a GPUTextureFormat is the number of bytes needed to store one texel block. It is not fully defined for all formats. This value is informative and non-normative.

enum GPUTextureFormat {
    // 8-bit formats
    "r8unorm",
    "r8snorm",
    "r8uint",
    "r8sint",

    // 16-bit formats
    "r16uint",
    "r16sint",
    "r16float",
    "rg8unorm",
    "rg8snorm",
    "rg8uint",
    "rg8sint",

    // 32-bit formats
    "r32uint",
    "r32sint",
    "r32float",
    "rg16uint",
    "rg16sint",
    "rg16float",
    "rgba8unorm",
    "rgba8unorm-srgb",
    "rgba8snorm",
    "rgba8uint",
    "rgba8sint",
    "bgra8unorm",
    "bgra8unorm-srgb",
    // Packed 32-bit formats
    "rgb9e5ufloat",
    "rgb10a2uint",
    "rgb10a2unorm",
    "rg11b10ufloat",

    // 64-bit formats
    "rg32uint",
    "rg32sint",
    "rg32float",
    "rgba16uint",
    "rgba16sint",
    "rgba16float",

    // 128-bit formats
    "rgba32uint",
    "rgba32sint",
    "rgba32float",

    // Depth/stencil formats
    "stencil8",
    "depth16unorm",
    "depth24plus",
    "depth24plus-stencil8",
    "depth32float",

    // "depth32float-stencil8" feature
    "depth32float-stencil8",

    // BC compressed formats usable if "texture-compression-bc" is both
    // supported by the device/user agent and enabled in requestDevice.
    "bc1-rgba-unorm",
    "bc1-rgba-unorm-srgb",
    "bc2-rgba-unorm",
    "bc2-rgba-unorm-srgb",
    "bc3-rgba-unorm",
    "bc3-rgba-unorm-srgb",
    "bc4-r-unorm",
    "bc4-r-snorm",
    "bc5-rg-unorm",
    "bc5-rg-snorm",
    "bc6h-rgb-ufloat",
    "bc6h-rgb-float",
    "bc7-rgba-unorm",
    "bc7-rgba-unorm-srgb",

    // ETC2 compressed formats usable if "texture-compression-etc2" is both
    // supported by the device/user agent and enabled in requestDevice.
    "etc2-rgb8unorm",
    "etc2-rgb8unorm-srgb",
    "etc2-rgb8a1unorm",
    "etc2-rgb8a1unorm-srgb",
    "etc2-rgba8unorm",
    "etc2-rgba8unorm-srgb",
    "eac-r11unorm",
    "eac-r11snorm",
    "eac-rg11unorm",
    "eac-rg11snorm",

    // ASTC compressed formats usable if "texture-compression-astc" is both
    // supported by the device/user agent and enabled in requestDevice.
    "astc-4x4-unorm",
    "astc-4x4-unorm-srgb",
    "astc-5x4-unorm",
    "astc-5x4-unorm-srgb",
    "astc-5x5-unorm",
    "astc-5x5-unorm-srgb",
    "astc-6x5-unorm",
    "astc-6x5-unorm-srgb",
    "astc-6x6-unorm",
    "astc-6x6-unorm-srgb",
    "astc-8x5-unorm",
    "astc-8x5-unorm-srgb",
    "astc-8x6-unorm",
    "astc-8x6-unorm-srgb",
    "astc-8x8-unorm",
    "astc-8x8-unorm-srgb",
    "astc-10x5-unorm",
    "astc-10x5-unorm-srgb",
    "astc-10x6-unorm",
    "astc-10x6-unorm-srgb",
    "astc-10x8-unorm",
    "astc-10x8-unorm-srgb",
    "astc-10x10-unorm",
    "astc-10x10-unorm-srgb",
    "astc-12x10-unorm",
    "astc-12x10-unorm-srgb",
    "astc-12x12-unorm",
    "astc-12x12-unorm-srgb",
};

The depth component of the "depth24plus" and "depth24plus-stencil8" formats may be implemented as either a 24-bit depth value or a "depth32float" value.

The stencil8 format may be implemented as either a real "stencil8", or "depth24stencil8", where the depth aspect is hidden and inaccessible.

NOTE:
While the precision of depth32float channels is strictly higher than the precision of 24-bit depth channels for all values in the representable range (0.0 to 1.0), note that the set of representable values is not an exact superset.

A format is renderable if it is either a color renderable format, or a depth-or-stencil format. If a format is listed in § 26.1.1 Plain color formats with RENDER_ATTACHMENT capability, it is a color renderable format. Any other format is not a color renderable format. All depth-or-stencil formats are renderable.

A renderable format is also blendable if it can be used with render pipeline blending. See § 26.1 Texture Format Capabilities.

A format is filterable if it supports the GPUTextureSampleType "float" (not just "unfilterable-float"); that is, it can be used with "filtering" GPUSamplers. See § 26.1 Texture Format Capabilities.

resolving GPUTextureAspect(format, aspect)

Arguments:

Returns: GPUTextureFormat or null

  1. If aspect is:

    "all"

    Return format.

    "depth-only"
    "stencil-only"

    If format is a depth-stencil-format: Return the aspect-specific format of format according to § 26.1.2 Depth-stencil formats or null if the aspect is not present in format.

  2. Return null.

Use of some texture formats require a feature to be enabled on the GPUDevice. Because new formats can be added to the specification, those enum values may not be known by the implementation. In order to normalize behavior across implementations, attempting to use a format that requires a feature will throw an exception if the associated feature is not enabled on the device. This makes the behavior the same as when the format is unknown to the implementation.

See § 26.1 Texture Format Capabilities for information about which GPUTextureFormats require features.

To Validate texture format required features of a GPUTextureFormat format
with logical device device, run the following content timeline steps:
  1. If format requires a feature and device.[[features]] does not contain the feature:

    1. Throw a TypeError.

6.4. GPUExternalTexture

A GPUExternalTexture is a sampleable 2D texture wrapping an external video object. The contents of a GPUExternalTexture object are a snapshot and may not change, either from inside WebGPU (it is only sampleable) or from outside WebGPU (e.g. due to video frame advancement).

They are bound into bind group layouts using the externalTexture bind group layout entry member. External textures use several binding slots: see Exceeds the binding slot limits.

NOTE:
External textures can be implemented without creating a copy of the imported source, but this depends implementation-defined factors. Ownership of the underlying representation may either be exclusive or shared with other owners (such as a video decoder), but this is not visible to the application.

The underlying representation of an external texture is unobservable (except for sampling behavior) but typically may include

The configuration used may not be stable across time, systems, user agents, media sources, or frames within a single video source. In order to account for many possible representations, the binding conservatively uses the following, for each external texture:

[Exposed=(Window, Worker), SecureContext]
interface GPUExternalTexture {
};
GPUExternalTexture includes GPUObjectBase;

GPUExternalTexture has the following immutable properties:

[[descriptor]], of type GPUExternalTextureDescriptor, readonly

The descriptor with which the texture was created.

GPUExternalTexture has the following immutable properties:

[[expired]], of type boolean, initially false

Indicates whether the object has expired (can no longer be used).

Note: Unlike [[destroyed]] slots, which are similar, this can change from true back to false.

6.4.1. Importing External Textures

An external texture is created from an external video object using importExternalTexture().

An external texture created from an HTMLVideoElement expires (is destroyed) automatically in a task after it is imported, instead of manually or upon garbage collection like other resources. When an external texture expires, its [[expired]] slot changes to true.

An external texture created from a VideoFrame expires (is destroyed) when, and only when, the source VideoFrame is closed, either explicitly by close(), or by other means.

Note: As noted in decode(), authors should call close() on output VideoFrames to avoid decoder stalls. If an imported VideoFrame is dropped without being closed, the imported GPUExternalTexture object will keep it alive until it is also dropped. The VideoFrame cannot be garbage collected until both objects are dropped. Garbage collection is unpredictable, so this may still stall the video decoder.

Once the GPUExternalTexture expires, importExternalTexture() must be called again. However, the user agent may un-expire and return the same GPUExternalTexture again, instead of creating a new one. This will commonly happen unless the execution of the application is scheduled to match the video’s frame rate (e.g. using requestVideoFrameCallback()). If the same object is returned again, it will compare equal, and GPUBindGroups, GPURenderBundles, etc. referencing the previous object can still be used.

dictionary GPUExternalTextureDescriptor
         : GPUObjectDescriptorBase {
    required (HTMLVideoElement or VideoFrame) source;
    PredefinedColorSpace colorSpace = "srgb";
};

GPUExternalTextureDescriptor dictionaries have the following members:

source, of type (HTMLVideoElement or VideoFrame)

The video source to import the external texture from. Source size is determined as described by the external source dimensions table.

colorSpace, of type PredefinedColorSpace, defaulting to "srgb"

The color space the image contents of source will be converted into when reading.

importExternalTexture(descriptor)

Creates a GPUExternalTexture wrapping the provided image source.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.importExternalTexture(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUExternalTextureDescriptor Provides the external image source object (and any creation options).

Returns: GPUExternalTexture

Content timeline steps:

  1. Let source be descriptor.source.

  2. If the current image contents of source are the same as the most recent importExternalTexture() call with the same descriptor (ignoring label), and the user agent chooses to reuse it:

    1. Let previousResult be the GPUExternalTexture returned previously.

    2. Set previousResult.[[expired]] to false, renewing ownership of the underlying resource.

    3. Let result be previousResult.

    Note: This allows the application to detect duplicate imports and avoid re-creating dependent objects (such as GPUBindGroups). Implementations still need to be able to handle a single frame being wrapped by multiple GPUExternalTexture, since import metadata like colorSpace can change even for the same frame.

    Otherwise:

    1. If source is not origin-clean, throw a SecurityError and return.

    2. Let usability be ? check the usability of the image argument(source).

    3. If usability is not good:

      1. Generate a validation error.

      2. Return an invalidated GPUExternalTexture.

    4. Let data be the result of converting the current image contents of source into the color space descriptor.colorSpace with unpremultiplied alpha.

      This may result in values outside of the range [0, 1]. If clamping is desired, it may be performed after sampling.

      Note: This is described like a copy, but may be implemented as a reference to read-only underlying data plus appropriate metadata to perform conversion later.

    5. Let result be a new GPUExternalTexture object wrapping data.

  3. If source is an HTMLVideoElement, queue an automatic expiry task with device this and the following steps:

    1. Set result.[[expired]] to true, releasing ownership of the underlying resource.

    Note: An HTMLVideoElement should be imported in the same task that samples the texture (which should generally be scheduled using requestVideoFrameCallback or requestAnimationFrame() depending on the application). Otherwise, a texture could get destroyed by these steps before the application is finished using it.

  4. If source is a VideoFrame, then when source is closed, run the following steps:

    1. Set result.[[expired]] to true.

  5. Set result.label to descriptor.label.

  6. Return result.

Rendering using an video element external texture at the page animation frame rate:
const videoElement = document.createElement('video');
// ... set up videoElement, wait for it to be ready...

function frame() {
    requestAnimationFrame(frame);

    // Always re-import the video on every animation frame, because the
    // import is likely to have expired.
    // The browser may cache and reuse a past frame, and if it does it
    // may return the same GPUExternalTexture object again.
    // In this case, old bind groups are still valid.
    const externalTexture = gpuDevice.importExternalTexture({
        source: videoElement
    });

    // ... render using externalTexture...
}
requestAnimationFrame(frame);
Rendering using an video element external texture at the video’s frame rate, if requestVideoFrameCallback is available:
const videoElement = document.createElement('video');
// ... set up videoElement...

function frame() {
    videoElement.requestVideoFrameCallback(frame);

    // Always re-import, because we know the video frame has advanced
    const externalTexture = gpuDevice.importExternalTexture({
        source: videoElement
    });

    // ... render using externalTexture...
}
videoElement.requestVideoFrameCallback(frame);

6.4.2. Sampling External Textures

External textures are represented in WGSL with texture_external and may be read using textureLoad and textureSampleBaseClampToEdge.

The sampler provided to textureSampleBaseClampToEdge is used to sample the underlying textures. The result is in the color space set by colorSpace. It is implementation-dependent whether, for any given external texture, the sampler (and filtering) is applied before or after conversion from underlying values into the specified color space.

Note: If the internal representation is an RGBA plane, sampling behaves as on a regular 2D texture. If there are several underlying planes (e.g. Y+UV), the sampler is used to sample each underlying texture separately, prior to conversion from YUV to the specified color space.

7. Samplers

7.1. GPUSampler

A GPUSampler encodes transformations and filtering information that can be used in a shader to interpret texture resource data.

GPUSamplers are created via createSampler().

[Exposed=(Window, Worker), SecureContext]
interface GPUSampler {
};
GPUSampler includes GPUObjectBase;

GPUSampler has the following immutable properties:

[[descriptor]], of type GPUSamplerDescriptor, readonly

The GPUSamplerDescriptor with which the GPUSampler was created.

[[isComparison]], of type boolean, readonly

Whether the GPUSampler is used as a comparison sampler.

[[isFiltering]], of type boolean, readonly

Whether the GPUSampler weights multiple samples of a texture.

7.1.1. GPUSamplerDescriptor

A GPUSamplerDescriptor specifies the options to use to create a GPUSampler.

dictionary GPUSamplerDescriptor
         : GPUObjectDescriptorBase {
    GPUAddressMode addressModeU = "clamp-to-edge";
    GPUAddressMode addressModeV = "clamp-to-edge";
    GPUAddressMode addressModeW = "clamp-to-edge";
    GPUFilterMode magFilter = "nearest";
    GPUFilterMode minFilter = "nearest";
    GPUMipmapFilterMode mipmapFilter = "nearest";
    float lodMinClamp = 0;
    float lodMaxClamp = 32;
    GPUCompareFunction compare;
    [Clamp] unsigned short maxAnisotropy = 1;
};
addressModeU, of type GPUAddressMode, defaulting to "clamp-to-edge"
addressModeV, of type GPUAddressMode, defaulting to "clamp-to-edge"
addressModeW, of type GPUAddressMode, defaulting to "clamp-to-edge"

Specifies the address modes for the texture width, height, and depth coordinates, respectively.

magFilter, of type GPUFilterMode, defaulting to "nearest"

Specifies the sampling behavior when the sampled area is smaller than or equal to one texel.

minFilter, of type GPUFilterMode, defaulting to "nearest"

Specifies the sampling behavior when the sampled area is larger than one texel.

mipmapFilter, of type GPUMipmapFilterMode, defaulting to "nearest"

Specifies behavior for sampling between mipmap levels.

lodMinClamp, of type float, defaulting to 0
lodMaxClamp, of type float, defaulting to 32

Specifies the minimum and maximum levels of detail, respectively, used internally when sampling a texture.

compare, of type GPUCompareFunction

When provided the sampler will be a comparison sampler with the specified GPUCompareFunction.

Note: Comparison samplers may use filtering, but the sampling results will be implementation-dependent and may differ from the normal filtering rules.

maxAnisotropy, of type unsigned short, defaulting to 1

Specifies the maximum anisotropy value clamp used by the sampler. Anisotropic filtering is enabled when maxAnisotropy is > 1 and the implementation supports it.

Anisotropic filtering improves the image quality of textures sampled at oblique viewing angles. Higher maxAnisotropy values indicate the maximum ratio of anisotropy supported when filtering.

NOTE:
Most implementations support maxAnisotropy values in range between 1 and 16, inclusive. The used value of maxAnisotropy will be clamped to the maximum value that the platform supports.

The precise filtering behavior is implementation-dependent.

Level of detail (LOD) describes which mip level(s) are selected when sampling a texture. It may be specified explicitly through shader methods like textureSampleLevel or implicitly determined from the texture coordinate derivatives.

Note: See Scale Factor Operation, LOD Operation and Image Level Selection in the Vulkan 1.4 spec for an example of how implicit LODs may be calculated.

GPUAddressMode describes the behavior of the sampler if the sampled texels extend beyond the bounds of the sampled texture.

enum GPUAddressMode {
    "clamp-to-edge",
    "repeat",
    "mirror-repeat",
};
"clamp-to-edge"

Texture coordinates are clamped between 0.0 and 1.0, inclusive.

"repeat"

Texture coordinates wrap to the other side of the texture.

"mirror-repeat"

Texture coordinates wrap to the other side of the texture, but the texture is flipped when the integer part of the coordinate is odd.

GPUFilterMode and GPUMipmapFilterMode describe the behavior of the sampler if the sampled area does not cover exactly one texel.

Note: See Texel Filtering in the Vulkan 1.4 spec for an example of how samplers may determine which texels are sampled from for the various filtering modes.

enum GPUFilterMode {
    "nearest",
    "linear",
};

enum GPUMipmapFilterMode {
    "nearest",
    "linear",
};
"nearest"

Return the value of the texel nearest to the texture coordinates.

"linear"

Select two texels in each dimension and return a linear interpolation between their values.

GPUCompareFunction specifies the behavior of a comparison sampler. If a comparison sampler is used in a shader, the depth_ref is compared to the fetched texel value, and the result of this comparison test is generated (1.0f for pass, or 0.0f for fail).

After comparison, if texture filtering is enabled, the filtering step occurs, so that comparison results are mixed together resulting in values in the range [0, 1]. Filtering should behave as usual, however it may be computed with lower precision or not mix results at all.

enum GPUCompareFunction {
    "never",
    "less",
    "equal",
    "less-equal",
    "greater",
    "not-equal",
    "greater-equal",
    "always",
};
"never"

Comparison tests never pass.

"less"

A provided value passes the comparison test if it is less than the sampled value.

"equal"

A provided value passes the comparison test if it is equal to the sampled value.

"less-equal"

A provided value passes the comparison test if it is less than or equal to the sampled value.

"greater"

A provided value passes the comparison test if it is greater than the sampled value.

"not-equal"

A provided value passes the comparison test if it is not equal to the sampled value.

"greater-equal"

A provided value passes the comparison test if it is greater than or equal to the sampled value.

"always"

Comparison tests always pass.

7.1.2. Sampler Creation

createSampler(descriptor)

Creates a GPUSampler.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createSampler(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUSamplerDescriptor Description of the GPUSampler to create.

Returns: GPUSampler

Content timeline steps:

  1. Let s be ! create a new WebGPU object(this, GPUSampler, descriptor).

  2. Issue the initialization steps on the Device timeline of this.

  3. Return s.

Device timeline initialization steps:
  1. If any of the following conditions are unsatisfied generate a validation error, invalidate s and return.

  2. Set s.[[descriptor]] to descriptor.

  3. Set s.[[isComparison]] to false if the compare attribute of s.[[descriptor]] is null or undefined. Otherwise, set it to true.

  4. Set s.[[isFiltering]] to false if none of minFilter, magFilter, or mipmapFilter has the value of "linear". Otherwise, set it to true.

Creating a GPUSampler that does trilinear filtering and repeats texture coordinates:
const sampler = gpuDevice.createSampler({
    addressModeU: 'repeat',
    addressModeV: 'repeat',
    magFilter: 'linear',
    minFilter: 'linear',
    mipmapFilter: 'linear',
});

8. Resource Binding

8.1. GPUBindGroupLayout

A GPUBindGroupLayout defines the interface between a set of resources bound in a GPUBindGroup and their accessibility in shader stages.

[Exposed=(Window, Worker), SecureContext]
interface GPUBindGroupLayout {
};
GPUBindGroupLayout includes GPUObjectBase;

GPUBindGroupLayout has the following immutable properties:

[[descriptor]], of type GPUBindGroupLayoutDescriptor, readonly

8.1.1. Bind Group Layout Creation

A GPUBindGroupLayout is created via GPUDevice.createBindGroupLayout().

dictionary GPUBindGroupLayoutDescriptor
         : GPUObjectDescriptorBase {
    required sequence<GPUBindGroupLayoutEntry> entries;
};

GPUBindGroupLayoutDescriptor dictionaries have the following members:

entries, of type sequence<GPUBindGroupLayoutEntry>

A list of entries describing the shader resource bindings for a bind group.

A GPUBindGroupLayoutEntry describes a single shader resource binding to be included in a GPUBindGroupLayout.

dictionary GPUBindGroupLayoutEntry {
    required GPUIndex32 binding;
    required GPUShaderStageFlags visibility;

    GPUBufferBindingLayout buffer;
    GPUSamplerBindingLayout sampler;
    GPUTextureBindingLayout texture;
    GPUStorageTextureBindingLayout storageTexture;
    GPUExternalTextureBindingLayout externalTexture;
};

GPUBindGroupLayoutEntry dictionaries have the following members:

binding, of type GPUIndex32

A unique identifier for a resource binding within the GPUBindGroupLayout, corresponding to a GPUBindGroupEntry.binding and a @binding attribute in the GPUShaderModule.

visibility, of type GPUShaderStageFlags

A bitset of the members of GPUShaderStage. Each set bit indicates that a GPUBindGroupLayoutEntry's resource will be accessible from the associated shader stage.

buffer, of type GPUBufferBindingLayout

When provided, indicates the binding resource type for this GPUBindGroupLayoutEntry is GPUBufferBinding.

sampler, of type GPUSamplerBindingLayout

When provided, indicates the binding resource type for this GPUBindGroupLayoutEntry is GPUSampler.

texture, of type GPUTextureBindingLayout

When provided, indicates the binding resource type for this GPUBindGroupLayoutEntry is GPUTextureView.

storageTexture, of type GPUStorageTextureBindingLayout

When provided, indicates the binding resource type for this GPUBindGroupLayoutEntry is GPUTextureView.

externalTexture, of type GPUExternalTextureBindingLayout

When provided, indicates the binding resource type for this GPUBindGroupLayoutEntry is GPUExternalTexture.

typedef [EnforceRange] unsigned long GPUShaderStageFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUShaderStage {
    const GPUFlagsConstant VERTEX   = 0x1;
    const GPUFlagsConstant FRAGMENT = 0x2;
    const GPUFlagsConstant COMPUTE  = 0x4;
};

GPUShaderStage contains the following flags, which describe which shader stages a corresponding GPUBindGroupEntry for this GPUBindGroupLayoutEntry will be visible to:

VERTEX

The bind group entry will be accessible to vertex shaders.

FRAGMENT

The bind group entry will be accessible to fragment shaders.

COMPUTE

The bind group entry will be accessible to compute shaders.

The binding member of a GPUBindGroupLayoutEntry is determined by which member of the GPUBindGroupLayoutEntry is defined: buffer, sampler, texture, storageTexture, or externalTexture. Only one may be defined for any given GPUBindGroupLayoutEntry. Each member has an associated GPUBindingResource type and each binding type has an associated internal usage, given by this table:

Binding member Resource type Binding type
Binding usage
buffer GPUBufferBinding "uniform" constant
"storage" storage
"read-only-storage" storage-read
sampler GPUSampler "filtering" constant
"non-filtering"
"comparison"
texture GPUTextureView "float" constant
"unfilterable-float"
"depth"
"sint"
"uint"
storageTexture GPUTextureView "write-only" storage
"read-write"
"read-only" storage-read
externalTexture GPUExternalTexture constant
The list of GPUBindGroupLayoutEntry values entries exceeds the binding slot limits of supported limits limits if the number of slots used toward a limit exceeds the supported value in limits. Each entry may use multiple slots toward multiple limits.

Device timeline steps:

  1. For each entry in entries, if:

    entry.buffer?.type is "uniform" and entry.buffer?.hasDynamicOffset is true

    Consider 1 maxDynamicUniformBuffersPerPipelineLayout slot to be used.

    entry.buffer?.type is "storage" and entry.buffer?.hasDynamicOffset is true

    Consider 1 maxDynamicStorageBuffersPerPipelineLayout slot to be used.

  2. For each shader stage stage in « VERTEX, FRAGMENT, COMPUTE »:

    1. For each entry in entries for which entry.visibility contains stage, if:

      entry.buffer?.type is "uniform"

      Consider 1 maxUniformBuffersPerShaderStage slot to be used.

      entry.buffer?.type is "storage" or "read-only-storage"

      Consider 1 maxStorageBuffersPerShaderStage slot to be used.

      entry.sampler is provided

      Consider 1 maxSamplersPerShaderStage slot to be used.

      entry.texture is provided

      Consider 1 maxSampledTexturesPerShaderStage slot to be used.

      entry.storageTexture is provided

      Consider 1 maxStorageTexturesPerShaderStage slot to be used.

      entry.externalTexture is provided

      Consider 4 maxSampledTexturesPerShaderStage slot, 1 maxSamplersPerShaderStage slot, and 1 maxUniformBuffersPerShaderStage slot to be used.

enum GPUBufferBindingType {
    "uniform",
    "storage",
    "read-only-storage",
};

dictionary GPUBufferBindingLayout {
    GPUBufferBindingType type = "uniform";
    boolean hasDynamicOffset = false;
    GPUSize64 minBindingSize = 0;
};

GPUBufferBindingLayout dictionaries have the following members:

type, of type GPUBufferBindingType, defaulting to "uniform"

Indicates the type required for buffers bound to this bindings.

hasDynamicOffset, of type boolean, defaulting to false

Indicates whether this binding requires a dynamic offset.

minBindingSize, of type GPUSize64, defaulting to 0

Indicates the minimum size of a buffer binding used with this bind point.

Bindings are always validated against this size in createBindGroup().

If this is not 0, pipeline creation additionally validates that this value ≥ the minimum buffer binding size of the variable.

If this is 0, it is ignored by pipeline creation, and instead draw/dispatch commands validate that each binding in the GPUBindGroup satisfies the minimum buffer binding size of the variable.

Note: Similar execution-time validation is theoretically possible for other binding-related fields specified for early validation, like sampleType and format, which currently can only be validated in pipeline creation. However, such execution-time validation could be costly or unnecessarily complex, so it is available only for minBindingSize which is expected to have the most ergonomic impact.

enum GPUSamplerBindingType {
    "filtering",
    "non-filtering",
    "comparison",
};

dictionary GPUSamplerBindingLayout {
    GPUSamplerBindingType type = "filtering";
};

GPUSamplerBindingLayout dictionaries have the following members:

type, of type GPUSamplerBindingType, defaulting to "filtering"

Indicates the required type of a sampler bound to this bindings.

enum GPUTextureSampleType {
    "float",
    "unfilterable-float",
    "depth",
    "sint",
    "uint",
};

dictionary GPUTextureBindingLayout {
    GPUTextureSampleType sampleType = "float";
    GPUTextureViewDimension viewDimension = "2d";
    boolean multisampled = false;
};

GPUTextureBindingLayout dictionaries have the following members:

sampleType, of type GPUTextureSampleType, defaulting to "float"

Indicates the type required for texture views bound to this binding.

viewDimension, of type GPUTextureViewDimension, defaulting to "2d"

Indicates the required dimension for texture views bound to this binding.

multisampled, of type boolean, defaulting to false

Indicates whether or not texture views bound to this binding must be multisampled.

enum GPUStorageTextureAccess {
    "write-only",
    "read-only",
    "read-write",
};

dictionary GPUStorageTextureBindingLayout {
    GPUStorageTextureAccess access = "write-only";
    required GPUTextureFormat format;
    GPUTextureViewDimension viewDimension = "2d";
};

GPUStorageTextureBindingLayout dictionaries have the following members:

access, of type GPUStorageTextureAccess, defaulting to "write-only"

The access mode for this binding, indicating readability and writability.

format, of type GPUTextureFormat

The required format of texture views bound to this binding.

viewDimension, of type GPUTextureViewDimension, defaulting to "2d"

Indicates the required dimension for texture views bound to this binding.

dictionary GPUExternalTextureBindingLayout {
};

A GPUBindGroupLayout object has the following device timeline properties:

[[entryMap]], of type ordered map<GPUSize32, GPUBindGroupLayoutEntry>, readonly

The map of binding indices pointing to the GPUBindGroupLayoutEntrys, which this GPUBindGroupLayout describes.

[[dynamicOffsetCount]], of type GPUSize32, readonly

The number of buffer bindings with dynamic offsets in this GPUBindGroupLayout.

[[exclusivePipeline]], of type GPUPipelineBase?, readonly

The pipeline that created this GPUBindGroupLayout, if it was created as part of a default pipeline layout. If not null, GPUBindGroups created with this GPUBindGroupLayout can only be used with the specified GPUPipelineBase.

createBindGroupLayout(descriptor)

Creates a GPUBindGroupLayout.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createBindGroupLayout(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUBindGroupLayoutDescriptor Description of the GPUBindGroupLayout to create.

Returns: GPUBindGroupLayout

Content timeline steps:

  1. For each GPUBindGroupLayoutEntry entry in descriptor.entries:

    1. If entry.storageTexture is provided:

      1. ? Validate texture format required features for entry.storageTexture.format with this.[[device]].

  2. Let layout be ! create a new WebGPU object(this, GPUBindGroupLayout, descriptor).

  3. Issue the initialization steps on the Device timeline of this.

  4. Return layout.

Device timeline initialization steps:
  1. If any of the following conditions are unsatisfied generate a validation error, invalidate layout and return.

  2. Set layout.[[descriptor]] to descriptor.

  3. Set layout.[[dynamicOffsetCount]] to the number of entries in descriptor where buffer is provided and buffer.hasDynamicOffset is true.

  4. Set layout.[[exclusivePipeline]] to null.

  5. For each GPUBindGroupLayoutEntry entry in descriptor.entries:

    1. Insert entry into layout.[[entryMap]] with the key of entry.binding.

8.1.2. Compatibility

Two GPUBindGroupLayout objects a and b are considered group-equivalent if and only if all of the following conditions are satisfied:

If bind groups layouts are group-equivalent they can be interchangeably used in all contents.

8.2. GPUBindGroup

A GPUBindGroup defines a set of resources to be bound together in a group and how the resources are used in shader stages.

[Exposed=(Window, Worker), SecureContext]
interface GPUBindGroup {
};
GPUBindGroup includes GPUObjectBase;

GPUBindGroup has the following device timeline properties:

[[layout]], of type GPUBindGroupLayout, readonly

The GPUBindGroupLayout associated with this GPUBindGroup.

[[entries]], of type sequence<GPUBindGroupEntry>, readonly

The set of GPUBindGroupEntrys this GPUBindGroup describes.

[[usedResources]], of type usage scope, readonly

The set of buffer and texture subresources used by this bind group, associated with lists of the internal usage flags.

The bound buffer ranges of a GPUBindGroup bindGroup, given list<GPUBufferDynamicOffset> dynamicOffsets, are computed as follows:
  1. Let result be a new set<(GPUBindGroupLayoutEntry, GPUBufferBinding)>.

  2. Let dynamicOffsetIndex be 0.

  3. For each GPUBindGroupEntry bindGroupEntry in bindGroup.[[entries]], sorted by bindGroupEntry.binding:

    1. Let bindGroupLayoutEntry be bindGroup.[[layout]].[[entryMap]][bindGroupEntry.binding].

    2. If bindGroupLayoutEntry.buffer is not provided, continue.

    3. Let bound be a copy of bindGroupEntry.resource.

    4. Assert bound is a GPUBufferBinding.

    5. If bindGroupLayoutEntry.buffer.hasDynamicOffset:

      1. Increment bound.offset by dynamicOffsets[dynamicOffsetIndex].

      2. Increment dynamicOffsetIndex by 1.

    6. Append (bindGroupLayoutEntry, bound) to result.

  4. Return result.

8.2.1. Bind Group Creation

A GPUBindGroup is created via GPUDevice.createBindGroup().

dictionary GPUBindGroupDescriptor
         : GPUObjectDescriptorBase {
    required GPUBindGroupLayout layout;
    required sequence<GPUBindGroupEntry> entries;
};

GPUBindGroupDescriptor dictionaries have the following members:

layout, of type GPUBindGroupLayout

The GPUBindGroupLayout the entries of this bind group will conform to.

entries, of type sequence<GPUBindGroupEntry>

A list of entries describing the resources to expose to the shader for each binding described by the layout.

typedef (GPUSampler or GPUTextureView or GPUBufferBinding or GPUExternalTexture) GPUBindingResource;

dictionary GPUBindGroupEntry {
    required GPUIndex32 binding;
    required GPUBindingResource resource;
};

A GPUBindGroupEntry describes a single resource to be bound in a GPUBindGroup, and has the following members:

binding, of type GPUIndex32

A unique identifier for a resource binding within the GPUBindGroup, corresponding to a GPUBindGroupLayoutEntry.binding and a @binding attribute in the GPUShaderModule.

resource, of type GPUBindingResource

The resource to bind, which may be a GPUSampler, GPUTextureView, GPUExternalTexture, or GPUBufferBinding.

GPUBindGroupEntry has the following device timeline properties:

[[prevalidatedSize]], of type boolean

Whether or not this binding entry had its buffer size validated at time of creation.

dictionary GPUBufferBinding {
    required GPUBuffer buffer;
    GPUSize64 offset = 0;
    GPUSize64 size;
};

A GPUBufferBinding describes a buffer and optional range to bind as a resource, and has the following members:

buffer, of type GPUBuffer

The GPUBuffer to bind.

offset, of type GPUSize64, defaulting to 0

The offset, in bytes, from the beginning of buffer to the beginning of the range exposed to the shader by the buffer binding.

size, of type GPUSize64

The size, in bytes, of the buffer binding. If not provided, specifies the range starting at offset and ending at the end of buffer.

createBindGroup(descriptor)

Creates a GPUBindGroup.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createBindGroup(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUBindGroupDescriptor Description of the GPUBindGroup to create.

Returns: GPUBindGroup

Content timeline steps:

  1. Let bindGroup be ! create a new WebGPU object(this, GPUBindGroup, descriptor).

  2. Issue the initialization steps on the Device timeline of this.

  3. Return bindGroup.

Device timeline initialization steps:
  1. Let limits be this.[[device]].[[limits]].

  2. If any of the following conditions are unsatisfied generate a validation error, invalidate bindGroup and return.

    For each GPUBindGroupEntry bindingDescriptor in descriptor.entries:

  3. Let bindGroup.[[layout]] = descriptor.layout.

  4. Let bindGroup.[[entries]] = descriptor.entries.

  5. Let bindGroup.[[usedResources]] = {}.

  6. For each GPUBindGroupEntry bindingDescriptor in descriptor.entries:

    1. Let internalUsage be the binding usage for layoutBinding.

    2. Each subresource seen by resource is added to [[usedResources]] as internalUsage.

    3. Let bindingDescriptor.[[prevalidatedSize]] be false if the defined binding member for layoutBinding is buffer and layoutBinding.buffer.minBindingSize is 0, and true otherwise.

effective buffer binding size(binding)

Arguments:

Returns: GPUSize64

  1. If binding.size is not provided:

    1. Return max(0, binding.buffer.size - binding.offset);

  2. Return binding.size.

Two GPUBufferBinding objects a and b are considered buffer-binding-aliasing if and only if all of the following are true:

Note: When doing this calculation, any dynamic offsets have already been applied to the ranges.

8.3. GPUPipelineLayout

A GPUPipelineLayout defines the mapping between resources of all GPUBindGroup objects set up during command encoding in setBindGroup(), and the shaders of the pipeline set by GPURenderCommandsMixin.setPipeline or GPUComputePassEncoder.setPipeline.

The full binding address of a resource can be defined as a trio of:

  1. shader stage mask, to which the resource is visible

  2. bind group index

  3. binding number

The components of this address can also be seen as the binding space of a pipeline. A GPUBindGroup (with the corresponding GPUBindGroupLayout) covers that space for a fixed bind group index. The contained bindings need to be a superset of the resources used by the shader at this bind group index.

[Exposed=(Window, Worker), SecureContext]
interface GPUPipelineLayout {
};
GPUPipelineLayout includes GPUObjectBase;

GPUPipelineLayout has the following device timeline properties:

[[bindGroupLayouts]], of type list<GPUBindGroupLayout>, readonly

The GPUBindGroupLayout objects provided at creation in GPUPipelineLayoutDescriptor.bindGroupLayouts.

Note: using the same GPUPipelineLayout for many GPURenderPipeline or GPUComputePipeline pipelines guarantees that the user agent doesn’t need to rebind any resources internally when there is a switch between these pipelines.

GPUComputePipeline object X was created with GPUPipelineLayout.bindGroupLayouts A, B, C. GPUComputePipeline object Y was created with GPUPipelineLayout.bindGroupLayouts A, D, C. Supposing the command encoding sequence has two dispatches:
  1. setBindGroup(0, ...)

  2. setBindGroup(1, ...)

  3. setBindGroup(2, ...)

  4. setPipeline(X)

  5. dispatchWorkgroups()

  6. setBindGroup(1, ...)

  7. setPipeline(Y)

  8. dispatchWorkgroups()

In this scenario, the user agent would have to re-bind the group slot 2 for the second dispatch, even though neither the GPUBindGroupLayout at index 2 of GPUPipelineLayout.bindGroupLayouts, or the GPUBindGroup at slot 2, change.

Note: the expected usage of the GPUPipelineLayout is placing the most common and the least frequently changing bind groups at the "bottom" of the layout, meaning lower bind group slot numbers, like 0 or 1. The more frequently a bind group needs to change between draw calls, the higher its index should be. This general guideline allows the user agent to minimize state changes between draw calls, and consequently lower the CPU overhead.

8.3.1. Pipeline Layout Creation

A GPUPipelineLayout is created via GPUDevice.createPipelineLayout().

dictionary GPUPipelineLayoutDescriptor
         : GPUObjectDescriptorBase {
    required sequence<GPUBindGroupLayout> bindGroupLayouts;
};

GPUPipelineLayoutDescriptor dictionaries define all the GPUBindGroupLayouts used by a pipeline, and have the following members:

bindGroupLayouts, of type sequence<GPUBindGroupLayout>

A list of GPUBindGroupLayouts the pipeline will use. Each element corresponds to a @group attribute in the GPUShaderModule, with the Nth element corresponding with @group(N).

createPipelineLayout(descriptor)

Creates a GPUPipelineLayout.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createPipelineLayout(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUPipelineLayoutDescriptor Description of the GPUPipelineLayout to create.

Returns: GPUPipelineLayout

Content timeline steps:

  1. Let pl be ! create a new WebGPU object(this, GPUPipelineLayout, descriptor).

  2. Issue the initialization steps on the Device timeline of this.

  3. Return pl.

Device timeline initialization steps:
  1. Let limits be this.[[device]].[[limits]].

  2. Let allEntries be the result of concatenating bgl.[[descriptor]].entries for all bgl in descriptor.bindGroupLayouts.

  3. If any of the following conditions are unsatisfied generate a validation error, invalidate pl and return.

  4. Set the pl.[[bindGroupLayouts]] to descriptor.bindGroupLayouts.

Note: two GPUPipelineLayout objects are considered equivalent for any usage if their internal [[bindGroupLayouts]] sequences contain GPUBindGroupLayout objects that are group-equivalent.

8.4. Example

Create a GPUBindGroupLayout that describes a binding with a uniform buffer, a texture, and a sampler. Then create a GPUBindGroup and a GPUPipelineLayout using the GPUBindGroupLayout.
const bindGroupLayout = gpuDevice.createBindGroupLayout({
    entries: [{
        binding: 0,
        visibility: GPUShaderStage.VERTEX | GPUShaderStage.FRAGMENT,
        buffer: {}
    }, {
        binding: 1,
        visibility: GPUShaderStage.FRAGMENT,
        texture: {}
    }, {
        binding: 2,
        visibility: GPUShaderStage.FRAGMENT,
        sampler: {}
    }]
});

const bindGroup = gpuDevice.createBindGroup({
    layout: bindGroupLayout,
    entries: [{
        binding: 0,
        resource: { buffer: buffer },
    }, {
        binding: 1,
        resource: texture
    }, {
        binding: 2,
        resource: sampler
    }]
});

const pipelineLayout = gpuDevice.createPipelineLayout({
    bindGroupLayouts: [bindGroupLayout]
});

9. Shader Modules

9.1. GPUShaderModule

[Exposed=(Window, Worker), SecureContext]
interface GPUShaderModule {
    Promise<GPUCompilationInfo> getCompilationInfo();
};
GPUShaderModule includes GPUObjectBase;

GPUShaderModule is a reference to an internal shader module object.

9.1.1. Shader Module Creation

dictionary GPUShaderModuleDescriptor
         : GPUObjectDescriptorBase {
    required USVString code;
    sequence<GPUShaderModuleCompilationHint> compilationHints = [];
};
code, of type USVString

The WGSL source code for the shader module.

compilationHints, of type sequence<GPUShaderModuleCompilationHint>, defaulting to []

A list of GPUShaderModuleCompilationHints.

Any hint provided by an application should contain information about one entry point of a pipeline that will eventually be created from the entry point.

Implementations should use any information present in the GPUShaderModuleCompilationHint to perform as much compilation as is possible within createShaderModule().

Aside from type-checking, these hints are not validated in any way.

NOTE:
Supplying information in compilationHints does not have any observable effect, other than performance. It may be detrimental to performance to provide hints for pipelines that never end up being created.

Because a single shader module can hold multiple entry points, and multiple pipelines can be created from a single shader module, it can be more performant for an implementation to do as much compilation as possible once in createShaderModule() rather than multiple times in the multiple calls to createComputePipeline() or createRenderPipeline().

Hints are only applied to the entry points they explicitly name. Unlike GPUProgrammableStage.entryPoint, there is no default, even if only one entry point is present in the module.

Note: Hints are not validated in an observable way, but user agents may surface identifiable errors (like unknown entry point names or incompatible pipeline layouts) to developers, for example in the browser developer console.

createShaderModule(descriptor)

Creates a GPUShaderModule.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createShaderModule(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUShaderModuleDescriptor Description of the GPUShaderModule to create.

Returns: GPUShaderModule

Content timeline steps:

  1. Let sm be ! create a new WebGPU object(this, GPUShaderModule, descriptor).

  2. Issue the initialization steps on the Device timeline of this.

  3. Return sm.

Device timeline initialization steps:
  1. Let error be any error that results from shader module creation with the WGSL source descriptor.code, or null if no errors occured.

  2. If any of the following requirements are unmet, generate a validation error, invalidate sm, and return.

    Note: Uncategorized errors cannot arise from shader module creation. Implementations which detect such errors during shader module creation must behave as if the shader module is valid, and defer surfacing the error until pipeline creation.

NOTE:
User agents should not include detailed compiler error messages or shader text in the message text of validation errors arising here: these details are accessible via getCompilationInfo(). User agents should surface human-readable, formatted error details to developers for easier debugging (for example as a warning in the browser developer console, expandable to show full shader source).

As shader compilation errors should be rare in production applications, user agents could choose to surface them to developers regardless of error handling (GPU error scopes or uncapturederror event handlers), e.g. as an expandable warning. If not, they should provide and document another way for developers to access human-readable error details, for example by adding a checkbox to show errors unconditionally, or by showing human-readable details when logging a GPUCompilationInfo object to the console.

Create a GPUShaderModule from WGSL code:
// A simple vertex and fragment shader pair that will fill the viewport with red.
const shaderSource = `
    var<private> pos : array<vec2<f32>, 3> = array<vec2<f32>, 3>(
        vec2(-1.0, -1.0), vec2(-1.0, 3.0), vec2(3.0, -1.0));

    @vertex
    fn vertexMain(@builtin(vertex_index) vertexIndex : u32) -> @builtin(position) vec4<f32> {
        return vec4(pos[vertexIndex], 1.0, 1.0);
    }

    @fragment
    fn fragmentMain() -> @location(0) vec4<f32> {
        return vec4(1.0, 0.0, 0.0, 1.0);
    }
`;

const shaderModule = gpuDevice.createShaderModule({
    code: shaderSource,
});
9.1.1.1. Shader Module Compilation Hints

Shader module compilation hints are optional, additional information indicating how a given GPUShaderModule entry point is intended to be used in the future. For some implementations this information may aid in compiling the shader module earlier, potentially increasing performance.

dictionary GPUShaderModuleCompilationHint {
    required USVString entryPoint;
    (GPUPipelineLayout or GPUAutoLayoutMode) layout;
};
layout, of type (GPUPipelineLayout or GPUAutoLayoutMode)

A GPUPipelineLayout that the GPUShaderModule may be used with in a future createComputePipeline() or createRenderPipeline() call. If set to "auto" the layout will be the default pipeline layout for the entry point associated with this hint will be used.

NOTE:
If possible, authors should be supplying the same information to createShaderModule() and createComputePipeline() / createRenderPipeline().

If an application is unable to provide hint information at the time of calling createShaderModule(), it should usually not delay calling createShaderModule(), but instead just omit the unknown information from the compilationHints sequence or the individual members of GPUShaderModuleCompilationHint. Omitting this information may cause compilation to be deferred to createComputePipeline() / createRenderPipeline().

If an author is not confident that the hint information passed to createShaderModule() will match the information later passed to createComputePipeline() / createRenderPipeline() with that same module, they should avoid passing that information to createShaderModule(), as passing mismatched information to createShaderModule() may cause unnecessary compilations to occur.

9.1.2. Shader Module Compilation Information

enum GPUCompilationMessageType {
    "error",
    "warning",
    "info",
};

[Exposed=(Window, Worker), Serializable, SecureContext]
interface GPUCompilationMessage {
    readonly attribute DOMString message;
    readonly attribute GPUCompilationMessageType type;
    readonly attribute unsigned long long lineNum;
    readonly attribute unsigned long long linePos;
    readonly attribute unsigned long long offset;
    readonly attribute unsigned long long length;
};

[Exposed=(Window, Worker), Serializable, SecureContext]
interface GPUCompilationInfo {
    readonly attribute FrozenArray<GPUCompilationMessage> messages;
};

A GPUCompilationMessage is an informational, warning, or error message generated by the GPUShaderModule compiler. The messages are intended to be human readable to help developers diagnose issues with their shader code. Each message may correspond to either a single point in the shader code, a substring of the shader code, or may not correspond to any specific point in the code at all.

GPUCompilationMessage has the following attributes:

message, of type DOMString, readonly

The human-readable, localizable text for this compilation message.

Note: The message should follow the best practices for language and direction information. This includes making use of any future standards which may emerge regarding the reporting of string language and direction metadata.

Editorial note: At the time of this writing, no language/direction recommendation is available that provides compatibility and consistency with legacy APIs, but when there is, adopt it formally.

type, of type GPUCompilationMessageType, readonly

The severity level of the message.

If the type is "error", it corresponds to a shader-creation error.

lineNum, of type unsigned long long, readonly

The line number in the shader code the message corresponds to. Value is one-based, such that a lineNum of 1 indicates the first line of the shader code. Lines are delimited by line breaks.

If the message corresponds to a substring this points to the line on which the substring begins. Must be 0 if the message does not correspond to any specific point in the shader code.

linePos, of type unsigned long long, readonly

The offset, in UTF-16 code units, from the beginning of line lineNum of the shader code to the point or beginning of the substring that the message corresponds to. Value is one-based, such that a linePos of 1 indicates the first code unit of the line.

If message corresponds to a substring this points to the first UTF-16 code unit of the substring. Must be 0 if the message does not correspond to any specific point in the shader code.

offset, of type unsigned long long, readonly

The offset from the beginning of the shader code in UTF-16 code units to the point or beginning of the substring that message corresponds to. Must reference the same position as lineNum and linePos. Must be 0 if the message does not correspond to any specific point in the shader code.

length, of type unsigned long long, readonly

The number of UTF-16 code units in the substring that message corresponds to. If the message does not correspond with a substring then length must be 0.

Note: GPUCompilationMessage.lineNum and GPUCompilationMessage.linePos are one-based since the most common use for them is expected to be printing human readable messages that can be correlated with the line and column numbers shown in many text editors.

Note: GPUCompilationMessage.offset and GPUCompilationMessage.length are appropriate to pass to substr() in order to retrieve the substring of the shader code the message corresponds to.

getCompilationInfo()

Returns any messages generated during the GPUShaderModule's compilation.

The locations, order, and contents of messages are implementation-defined In particular, messages may not be ordered by lineNum.

Called on: GPUShaderModule this

Returns: Promise<GPUCompilationInfo>

Content timeline steps:

  1. Let contentTimeline be the current Content timeline.

  2. Let promise be a new promise.

  3. Issue the synchronization steps on the Device timeline of this.

  4. Return promise.

Device timeline synchronization steps:
  1. Let event occur upon the (successful or unsuccessful) completion of shader module creation for this.

  2. Listen for timeline event event on this.[[device]], handled by the subsequent steps on contentTimeline.

Content timeline steps:
  1. Let info be a new GPUCompilationInfo.

  2. Let messages be a list of any errors, warnings, or informational messages generated during shader module creation for this, or the empty list [] if the device was lost.

  3. For each message in messages:

    1. Let m be a new GPUCompilationMessage.

    2. Set m.message to be the text of message.

    3. If message is a shader-creation error:

      Set m.type to "error"

      If message is a warning:

      Set m.type to "warning"

      Otherwise:

      Set m.type to "info"

    4. If message is associated with a specific substring or position within the shader code:
      1. Set m.lineNum to the one-based number of the first line that the message refers to.

      2. Set m.linePos to the one-based number of the first UTF-16 code units on m.lineNum that the message refers to, or 1 if the message refers to the entire line.

      3. Set m.offset to the number of UTF-16 code units from the beginning of the shader to beginning of the substring or position that message refers to.

      4. Set m.length the length of the substring in UTF-16 code units that message refers to, or 0 if message refers to a position

      Otherwise:
      1. Set m.lineNum to 0.

      2. Set m.linePos to 0.

      3. Set m.offset to 0.

      4. Set m.length to 0.

    5. Append m to info.messages.

  4. Resolve promise with info.

10. Pipelines

A pipeline, be it GPUComputePipeline or GPURenderPipeline, represents the complete function done by a combination of the GPU hardware, the driver, and the user agent, that process the input data in the shape of bindings and vertex buffers, and produces some output, like the colors in the output render targets.

Structurally, the pipeline consists of a sequence of programmable stages (shaders) and fixed-function states, such as the blending modes.

Note: Internally, depending on the target platform, the driver may convert some of the fixed-function states into shader code, and link it together with the shaders provided by the user. This linking is one of the reason the object is created as a whole.

This combination state is created as a single object (a GPUComputePipeline or GPURenderPipeline) and switched using one command (GPUComputePassEncoder.setPipeline() or GPURenderCommandsMixin.setPipeline() respectively).

There are two ways to create pipelines:

immediate pipeline creation

createComputePipeline() and createRenderPipeline() return a pipeline object which can be used immediately in a pass encoder.

When this fails, the pipeline object will be invalid and the call will generate either a validation error or an internal error.

Note: A handle object is returned immediately, but actual pipeline creation is not synchronous. If pipeline creation takes a long time, this can incur a stall in the device timeline at some point between the creation call and execution of the submit() in which it is first used. The point is unspecified, but most likely to be one of: at creation, at the first usage of the pipeline in setPipeline(), at the corresponding finish() of that GPUCommandEncoder or GPURenderBundleEncoder, or at submit() of that GPUCommandBuffer.

async pipeline creation

createComputePipelineAsync() and createRenderPipelineAsync() return a Promise which resolves to a pipeline object when creation of the pipeline has completed.

When this fails, the Promise rejects with a GPUPipelineError.

GPUPipelineError describes a pipeline creation failure.

[Exposed=(Window, Worker), SecureContext, Serializable]
interface GPUPipelineError : DOMException {
    constructor(optional DOMString message = "", GPUPipelineErrorInit options);
    readonly attribute GPUPipelineErrorReason reason;
};

dictionary GPUPipelineErrorInit {
    required GPUPipelineErrorReason reason;
};

enum GPUPipelineErrorReason {
    "validation",
    "internal",
};

GPUPipelineError constructor:

constructor()
Arguments:
Arguments for the GPUPipelineError.constructor() method.
Parameter Type Nullable Optional Description
message DOMString Error message of the base DOMException.
options GPUPipelineErrorInit Options specific to GPUPipelineError.

Content timeline steps:

  1. Set this.name to "GPUPipelineError".

  2. Set this.message to message.

  3. Set this.reason to options.reason.

GPUPipelineError has the following attributes:

reason, of type GPUPipelineErrorReason, readonly

A read-only slot-backed attribute exposing the type of error encountered in pipeline creation as a GPUPipelineErrorReason:

GPUPipelineError objects are serializable objects.

Their serialization steps, given value and serialized, are:
  1. Run the DOMException serialization steps given value and serialized.

Their deserialization steps, given value and serialized, are:
  1. Run the DOMException deserialization steps given value and serialized.

10.1. Base pipelines

enum GPUAutoLayoutMode {
    "auto",
};

dictionary GPUPipelineDescriptorBase
         : GPUObjectDescriptorBase {
    required (GPUPipelineLayout or GPUAutoLayoutMode) layout;
};
layout, of type (GPUPipelineLayout or GPUAutoLayoutMode)

The GPUPipelineLayout for this pipeline, or "auto" to generate the pipeline layout automatically.

Note: If "auto" is used the pipeline cannot share GPUBindGroups with any other pipelines.

interface mixin GPUPipelineBase {
    [NewObject] GPUBindGroupLayout getBindGroupLayout(unsigned long index);
};

GPUPipelineBase has the following device timeline properties:

[[layout]], of type GPUPipelineLayout

The definition of the layout of resources which can be used with this.

GPUPipelineBase has the following methods:

getBindGroupLayout(index)

Gets a GPUBindGroupLayout that is compatible with the GPUPipelineBase's GPUBindGroupLayout at index.

Called on: GPUPipelineBase this

Arguments:

Arguments for the GPUPipelineBase.getBindGroupLayout(index) method.
Parameter Type Nullable Optional Description
index unsigned long Index into the pipeline layout’s [[bindGroupLayouts]] sequence.

Returns: GPUBindGroupLayout

Content timeline steps:

  1. Let layout be a new GPUBindGroupLayout object.

  2. Issue the initialization steps on the Device timeline of this.

  3. Return layout.

Device timeline initialization steps:
  1. If any of the following conditions are unsatisfied generate a validation error, invalidate layout and return.

  2. Initialize layout so it is a copy of this.[[layout]].[[bindGroupLayouts]][index].

    Note: GPUBindGroupLayout is only ever used by-value, not by-reference, so this is equivalent to returning the same internal object with a new WebGPU interface. A new GPUBindGroupLayout WebGPU interface is returned each time to avoid a round-trip between the Content timeline and the Device timeline.

10.1.1. Default pipeline layout

A GPUPipelineBase object that was created with a layout set to "auto" has a default layout created and used instead.

Note: Default layouts are provided as a convenience for simple pipelines, but use of explicit layouts is recommended in most cases. Bind groups created from default layouts cannot be used with other pipelines, and the structure of the default layout may change when altering shaders, causing unexpected bind group creation errors.

To create a default pipeline layout for GPUPipelineBase pipeline, run the following device timeline steps:

  1. Let groupCount be 0.

  2. Let groupDescs be a sequence of device.[[limits]].maxBindGroups new GPUBindGroupLayoutDescriptor objects.

  3. For each groupDesc in groupDescs:

    1. Set groupDesc.entries to an empty sequence.

  4. For each GPUProgrammableStage stageDesc in the descriptor used to create pipeline:

    1. Let shaderStage be the GPUShaderStageFlags for the shader stage at which stageDesc is used in pipeline.

    2. Let entryPoint be get the entry point(shaderStage, stageDesc). Assert entryPoint is not null.

    3. For each resource resource statically used by entryPoint:

      1. Let group be resource’s "group" decoration.

      2. Let binding be resource’s "binding" decoration.

      3. Let entry be a new GPUBindGroupLayoutEntry.

      4. Set entry.binding to binding.

      5. Set entry.visibility to shaderStage.

      6. If resource is for a sampler binding:

        1. Let samplerLayout be a new GPUSamplerBindingLayout.

        2. Set entry.sampler to samplerLayout.

      7. If resource is for a comparison sampler binding:

        1. Let samplerLayout be a new GPUSamplerBindingLayout.

        2. Set samplerLayout.type to "comparison".

        3. Set entry.sampler to samplerLayout.

      8. If resource is for a buffer binding:

        1. Let bufferLayout be a new GPUBufferBindingLayout.

        2. Set bufferLayout.minBindingSize to resource’s minimum buffer binding size.

        3. If resource is for a read-only storage buffer:

          1. Set bufferLayout.type to "read-only-storage".

        4. If resource is for a storage buffer:

          1. Set bufferLayout.type to "storage".

        5. Set entry.buffer to bufferLayout.

      9. If resource is for a sampled texture binding:

        1. Let textureLayout be a new GPUTextureBindingLayout.

        2. If resource is a depth texture binding:

          Else if the sampled type of resource is:

          f32 and there exists a static use of resource by stageDesc in a texture builtin function call that also uses a sampler

          Set textureLayout.sampleType to "float"

          f32 otherwise

          Set textureLayout.sampleType to "unfilterable-float"

          i32

          Set textureLayout.sampleType to "sint"

          u32

          Set textureLayout.sampleType to "uint"

        3. Set textureLayout.viewDimension to resource’s dimension.

        4. If resource is for a multisampled texture:

          1. Set textureLayout.multisampled to true.

        5. Set entry.texture to textureLayout.

      10. If resource is for a storage texture binding:

        1. Let storageTextureLayout be a new GPUStorageTextureBindingLayout.

        2. Set storageTextureLayout.format to resource’s format.

        3. Set storageTextureLayout.viewDimension to resource’s dimension.

        4. If the access mode is:

          read

          Set textureLayout.access to "read-only".

          write

          Set textureLayout.access to "write-only".

          read_write

          Set textureLayout.access to "read-write".

        5. Set entry.storageTexture to storageTextureLayout.

      11. Set groupCount to max(groupCount, group + 1).

      12. If groupDescs[group] has an entry previousEntry with binding equal to binding:

        1. If entry has different visibility than previousEntry:

          1. Add the bits set in entry.visibility into previousEntry.visibility

        2. If resource is for a buffer binding and entry has greater buffer.minBindingSize than previousEntry:

          1. Set previousEntry.buffer.minBindingSize to entry.buffer.minBindingSize.

        3. If resource is a sampled texture binding and entry has different texture.sampleType than previousEntry and both entry and previousEntry have texture.sampleType of either "float" or "unfilterable-float":

          1. Set previousEntry.texture.sampleType to "float".

        4. If any other property is unequal between entry and previousEntry:

          1. Return null (which will cause the creation of the pipeline to fail).

        5. If resource is a storage texture binding, entry.storageTexture.access is "read-write", previousEntry.storageTexture.access is "write-only", and previousEntry.storageTexture.format is compatible with STORAGE_BINDING and "read-write" according to the § 26.1.1 Plain color formats table:

          1. Set previousEntry.storageTexture.access to "read-write".

      13. Else

        1. Append entry to groupDescs[group].

  5. Let groupLayouts be a new list.

  6. For each i from 0 to groupCount - 1, inclusive:

    1. Let groupDesc be groupDescs[i].

    2. Let bindGroupLayout be the result of calling device.createBindGroupLayout()(groupDesc).

    3. Set bindGroupLayout.[[exclusivePipeline]] to pipeline.

    4. Append bindGroupLayout to groupLayouts.

  7. Let desc be a new GPUPipelineLayoutDescriptor.

  8. Set desc.bindGroupLayouts to groupLayouts.

  9. Return device.createPipelineLayout()(desc).

10.1.2. GPUProgrammableStage

A GPUProgrammableStage describes the entry point in the user-provided GPUShaderModule that controls one of the programmable stages of a pipeline. Entry point names follow the rules defined in WGSL identifier comparison.

dictionary GPUProgrammableStage {
    required GPUShaderModule module;
    USVString entryPoint;
    record<USVString, GPUPipelineConstantValue> constants = {};
};

typedef double GPUPipelineConstantValue; // May represent WGSL's bool, f32, i32, u32, and f16 if enabled.

GPUProgrammableStage has the following members:

module, of type GPUShaderModule

The GPUShaderModule containing the code that this programmable stage will execute.

entryPoint, of type USVString

The name of the function in module that this stage will use to perform its work.

NOTE: Since the entryPoint dictionary member is not required, methods which consume a GPUProgrammableStage must use the "get the entry point" algorithm to determine which entry point it refers to.

constants, of type record<USVString, GPUPipelineConstantValue>, defaulting to {}

Specifies the values of pipeline-overridable constants in the shader module module.

Each such pipeline-overridable constant is uniquely identified by a single pipeline-overridable constant identifier string, representing the pipeline constant ID of the constant if its declaration specifies one, and otherwise the constant’s identifier name.

The key of each key-value pair must equal the identifier string of one such constant, with the comparison performed according to the rules for WGSL identifier comparison. When the pipeline is executed, that constant will have the specified value.

Values are specified as GPUPipelineConstantValue, which is a double. They are converted to WGSL type of the pipeline-overridable constant (bool/i32/u32/f32/f16). If conversion fails, a validation error is generated.

Pipeline-overridable constants defined in WGSL:
@id(0)      override has_point_light: bool = true;  // Algorithmic control.
@id(1200)   override specular_param: f32 = 2.3;     // Numeric control.
@id(1300)   override gain: f32;                     // Must be overridden.
            override width: f32 = 0.0;              // Specifed at the API level
                                                    //   using the name "width".
            override depth: f32;                    // Specifed at the API level
                                                    //   using the name "depth".
                                                    //   Must be overridden.
            override height = 2 * depth;            // The default value
                                                    // (if not set at the API level),
                                                    // depends on another
                                                    // overridable constant.

Corresponding JavaScript code, providing only the overrides which are required (have no defaults):

{
    // ...
    constants: {
        1300: 2.0,  // "gain"
        depth: -1,  // "depth"
    }
}

Corresponding JavaScript code, overriding all constants:

{
    // ...
    constants: {
        0: false,   // "has_point_light"
        1200: 3.0,  // "specular_param"
        1300: 2.0,  // "gain"
        width: 20,  // "width"
        depth: -1,  // "depth"
        height: 15, // "height"
    }
}
To get the entry point(GPUShaderStage stage, GPUProgrammableStage descriptor), run the following device timeline steps:
  1. If descriptor.entryPoint is provided:

    1. If descriptor.module contains an entry point whose name equals descriptor.entryPoint, and whose shader stage equals stage, return that entry point.

      Otherwise, return null.

    Otherwise:

    1. If there is exactly one entry point in descriptor.module whose shader stage equals stage, return that entry point.

      Otherwise, return null.

validating GPUProgrammableStage(stage, descriptor, layout, device)

Arguments:

All of the requirements in the following steps must be met. If any are unmet, return false; otherwise, return true.

  1. descriptor.module must be valid to use with device.

  2. Let entryPoint be get the entry point(stage, descriptor).

  3. entryPoint must not be null.

  4. For each binding that is statically used by entryPoint:

  5. For each texture builtin function call in any of the functions in the shader stage rooted at entryPoint, if it uses a textureBinding of sampled texture or depth texture type together with a samplerBinding of sampler type (excluding sampler_comparison):

    1. Let texture be the GPUBindGroupLayoutEntry corresponding to textureBinding.

    2. Let sampler be the GPUBindGroupLayoutEntry corresponding to samplerBinding.

    3. If sampler.type is "filtering", then texture.sampleType must be "float".

    Note: "comparison" samplers can also only be used with "depth" textures, because they are the only texture type that can be bound to WGSL texture_depth_* bindings.

  6. For each keyvalue in descriptor.constants:

    1. key must equal the pipeline-overridable constant identifier string of some pipeline-overridable constant defined in the shader module descriptor.module by the rules defined in WGSL identifier comparison. The pipeline-overridable constant is not required to be statically used by entryPoint. Let the type of that constant be T.

    2. Converting the IDL value value to WGSL type T must not throw a TypeError.

  7. For each pipeline-overridable constant identifier string key which is statically used by entryPoint:

  8. Pipeline-creation program errors must not result from the rules of the [WGSL] specification.

validating shader binding(variable, layout)

Arguments:

Let bindGroup be the bind group index, and bindIndex be the binding index, of the shader binding declaration variable.

Return true if all of the following conditions are satisfied:

The minimum buffer binding size for a buffer binding variable var is computed as follows:
  1. Let T be the store type of var.

  2. If T is a runtime-sized array, or contains a runtime-sized array, replace that array<E> with array<E, 1>.

    Note: This ensures there’s always enough memory for one element, which allows array indices to be clamped to the length of the array resulting in an in-memory access.

  3. Return SizeOf(T).

Note: Enforcing this lower bound ensures reads and writes via the buffer variable only access memory locations within the bound region of the buffer.

A resource binding, pipeline-overridable constant, shader stage input, or shader stage output is considered to be statically used by an entry point if it is present in the interface of the shader stage for that entry point.

10.2. GPUComputePipeline

A GPUComputePipeline is a kind of pipeline that controls the compute shader stage, and can be used in GPUComputePassEncoder.

Compute inputs and outputs are all contained in the bindings, according to the given GPUPipelineLayout. The outputs correspond to buffer bindings with a type of "storage" and storageTexture bindings with a type of "write-only" or "read-write".

Stages of a compute pipeline:

  1. Compute shader

[Exposed=(Window, Worker), SecureContext]
interface GPUComputePipeline {
};
GPUComputePipeline includes GPUObjectBase;
GPUComputePipeline includes GPUPipelineBase;

10.2.1. Compute Pipeline Creation

A GPUComputePipelineDescriptor describes a compute pipeline. See § 23.1 Computing for additional details.

dictionary GPUComputePipelineDescriptor
         : GPUPipelineDescriptorBase {
    required GPUProgrammableStage compute;
};

GPUComputePipelineDescriptor has the following members:

compute, of type GPUProgrammableStage

Describes the compute shader entry point of the pipeline.

createComputePipeline(descriptor)

Creates a GPUComputePipeline using immediate pipeline creation.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createComputePipeline(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUComputePipelineDescriptor Description of the GPUComputePipeline to create.

Returns: GPUComputePipeline

Content timeline steps:

  1. Let pipeline be ! create a new WebGPU object(this, GPUComputePipeline, descriptor).

  2. Issue the initialization steps on the Device timeline of this.

  3. Return pipeline.

Device timeline initialization steps:
  1. Let layout be a new default pipeline layout for pipeline if descriptor.layout is "auto", and descriptor.layout otherwise.

  2. All of the requirements in the following steps must be met. If any are unmet, generate a validation error, invalidate pipeline and return.

    1. layout must be valid to use with this.

    2. validating GPUProgrammableStage(COMPUTE, descriptor.compute, layout, this) must succeed.

    3. Let entryPoint be get the entry point(COMPUTE, descriptor.compute).

      Assert entryPoint is not null.

    4. Let workgroupStorageUsed be the sum of roundUp(16, SizeOf(T)) over each type T of all variables with address space "workgroup" statically used by entryPoint.

      workgroupStorageUsed must be ≤ device.limits.maxComputeWorkgroupStorageSize.

    5. entryPoint must use ≤ device.limits.maxComputeInvocationsPerWorkgroup per workgroup.

    6. Each component of entryPoint’s workgroup_size attribute must be ≤ the corresponding component in [device.limits.maxComputeWorkgroupSizeX, device.limits.maxComputeWorkgroupSizeY, device.limits.maxComputeWorkgroupSizeZ].

  3. If any pipeline-creation uncategorized errors result from the implementation of pipeline creation, generate an internal error, invalidate pipeline and return.

    Note: Even if the implementation detected uncategorized errors in shader module creation, the error is surfaced here.

  4. Set pipeline.[[layout]] to layout.

createComputePipelineAsync(descriptor)

Creates a GPUComputePipeline using async pipeline creation. The returned Promise resolves when the created pipeline is ready to be used without additional delay.

If pipeline creation fails, the returned Promise rejects with an GPUPipelineError. (A GPUError is not dispatched to the device.)

Note: Use of this method is preferred whenever possible, as it prevents blocking the queue timeline work on pipeline compilation.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createComputePipelineAsync(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUComputePipelineDescriptor Description of the GPUComputePipeline to create.

Returns: Promise<GPUComputePipeline>

Content timeline steps:

  1. Let contentTimeline be the current Content timeline.

  2. Let promise be a new promise.

  3. Issue the initialization steps on the Device timeline of this.

  4. Return promise.

Device timeline initialization steps:
  1. Let pipeline be a new GPUComputePipeline created as if this.createComputePipeline() was called with descriptor, except capturing any errors as error, rather than dispatching them to the device.

  2. Let event occur upon the (successful or unsuccessful) completion of pipeline creation for pipeline.

  3. Listen for timeline event event on this.[[device]], handled by the subsequent steps on the device timeline of this.

Device timeline steps:
  1. If pipeline is valid, this.[[device]].[[destroy started]] is true, or this is lost:

    1. Issue the following steps on contentTimeline:

      Content timeline steps:
      1. Resolve promise with pipeline.

    2. Return.

    Note: No errors are generated from a device which is lost or pending destruction. See § 22 Errors & Debugging.

  2. If pipeline is invalid and error is an internal error, issue the following steps on contentTimeline, and return.

  3. If pipeline is invalid and error is a validation error, issue the following steps on contentTimeline, and return.

Creating a simple GPUComputePipeline:
const computePipeline = gpuDevice.createComputePipeline({
    layout: pipelineLayout,
    compute: {
        module: computeShaderModule,
        entryPoint: 'computeMain',
    }
});

10.3. GPURenderPipeline

A GPURenderPipeline is a kind of pipeline that controls the vertex and fragment shader stages, and can be used in GPURenderPassEncoder as well as GPURenderBundleEncoder.

Render pipeline inputs are:

Render pipeline outputs are:

A render pipeline is comprised of the following render stages:

  1. Vertex fetch, controlled by GPUVertexState.buffers

  2. Vertex shader, controlled by GPUVertexState

  3. Primitive assembly, controlled by GPUPrimitiveState

  4. Rasterization, controlled by GPUPrimitiveState, GPUDepthStencilState, and GPUMultisampleState

  5. Fragment shader, controlled by GPUFragmentState

  6. Stencil test and operation, controlled by GPUDepthStencilState

  7. Depth test and write, controlled by GPUDepthStencilState

  8. Output merging, controlled by GPUFragmentState.targets

[Exposed=(Window, Worker), SecureContext]
interface GPURenderPipeline {
};
GPURenderPipeline includes GPUObjectBase;
GPURenderPipeline includes GPUPipelineBase;

GPURenderPipeline has the following device timeline properties:

[[descriptor]], of type GPURenderPipelineDescriptor, readonly

The GPURenderPipelineDescriptor describing this pipeline.

All optional fields of GPURenderPipelineDescriptor are defined.

[[writesDepth]], of type boolean, readonly

True if the pipeline writes to the depth component of the depth/stencil attachment

[[writesStencil]], of type boolean, readonly

True if the pipeline writes to the stencil component of the depth/stencil attachment

10.3.1. Render Pipeline Creation

A GPURenderPipelineDescriptor describes a render pipeline by configuring each of the render stages. See § 23.2 Rendering for additional details.

dictionary GPURenderPipelineDescriptor
         : GPUPipelineDescriptorBase {
    required GPUVertexState vertex;
    GPUPrimitiveState primitive = {};
    GPUDepthStencilState depthStencil;
    GPUMultisampleState multisample = {};
    GPUFragmentState fragment;
};

GPURenderPipelineDescriptor has the following members:

vertex, of type GPUVertexState

Describes the vertex shader entry point of the pipeline and its input buffer layouts.

primitive, of type GPUPrimitiveState, defaulting to {}

Describes the primitive-related properties of the pipeline.

depthStencil, of type GPUDepthStencilState

Describes the optional depth-stencil properties, including the testing, operations, and bias.

multisample, of type GPUMultisampleState, defaulting to {}

Describes the multi-sampling properties of the pipeline.

fragment, of type GPUFragmentState

Describes the fragment shader entry point of the pipeline and its output colors. If not provided, the § 23.2.8 No Color Output mode is enabled.

createRenderPipeline(descriptor)

Creates a GPURenderPipeline using immediate pipeline creation.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createRenderPipeline(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPURenderPipelineDescriptor Description of the GPURenderPipeline to create.

Returns: GPURenderPipeline

Content timeline steps:

  1. If descriptor.fragment is provided:

    1. For each non-null colorState of descriptor.fragment.targets:

      1. ? Validate texture format required features of colorState.format with this.[[device]].

  2. If descriptor.depthStencil is provided:

    1. ? Validate texture format required features of descriptor.depthStencil.format with this.[[device]].

  3. Let pipeline be ! create a new WebGPU object(this, GPURenderPipeline, descriptor).

  4. Issue the initialization steps on the Device timeline of this.

  5. Return pipeline.

Device timeline initialization steps:
  1. Let layout be a new default pipeline layout for pipeline if descriptor.layout is "auto", and descriptor.layout otherwise.

  2. All of the requirements in the following steps must be met. If any are unmet, generate a validation error, invalidate pipeline, and return.

    1. layout must be valid to use with this.

    2. validating GPURenderPipelineDescriptor(descriptor, layout, this) must succeed.

    3. Let vertexBufferCount be the index of the last non-null entry in descriptor.vertex.buffers, plus 1; or 0 if there are none.

    4. layout.[[bindGroupLayouts]].size + vertexBufferCount must be ≤ this.[[device]].[[limits]].maxBindGroupsPlusVertexBuffers.

  3. If any pipeline-creation uncategorized errors result from the implementation of pipeline creation, generate an internal error, invalidate pipeline and return.

    Note: Even if the implementation detected uncategorized errors in shader module creation, the error is surfaced here.

  4. Set pipeline.[[descriptor]] to descriptor.

  5. Set pipeline.[[writesDepth]] to false.

  6. Set pipeline.[[writesStencil]] to false.

  7. Let depthStencil be descriptor.depthStencil.

  8. If depthStencil is not null:

    1. If depthStencil.depthWriteEnabled is provided:

      1. Set pipeline.[[writesDepth]] to depthStencil.depthWriteEnabled.

    2. If depthStencil.stencilWriteMask is not 0:

      1. Let stencilFront be depthStencil.stencilFront.

      2. Let stencilBack be depthStencil.stencilBack.

      3. Let cullMode be descriptor.primitive.cullMode.

      4. If cullMode is not "front", and any of stencilFront.passOp, stencilFront.depthFailOp, or stencilFront.failOp is not "keep":

        1. Set pipeline.[[writesStencil]] to true.

      5. If cullMode is not "back", and any of stencilBack.passOp, stencilBack.depthFailOp, or stencilBack.failOp is not "keep":

        1. Set pipeline.[[writesStencil]] to true.

  9. Set pipeline.[[layout]] to layout.

createRenderPipelineAsync(descriptor)

Creates a GPURenderPipeline using async pipeline creation. The returned Promise resolves when the created pipeline is ready to be used without additional delay.

If pipeline creation fails, the returned Promise rejects with an GPUPipelineError. (A GPUError is not dispatched to the device.)

Note: Use of this method is preferred whenever possible, as it prevents blocking the queue timeline work on pipeline compilation.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createRenderPipelineAsync(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPURenderPipelineDescriptor Description of the GPURenderPipeline to create.

Returns: Promise<GPURenderPipeline>

Content timeline steps:

  1. Let contentTimeline be the current Content timeline.

  2. Let promise be a new promise.

  3. Issue the initialization steps on the Device timeline of this.

  4. Return promise.

Device timeline initialization steps:
  1. Let pipeline be a new GPURenderPipeline created as if this.createRenderPipeline() was called with descriptor, except capturing any errors as error, rather than dispatching them to the device.

  2. Let event occur upon the (successful or unsuccessful) completion of pipeline creation for pipeline.

  3. Listen for timeline event event on this.[[device]], handled by the subsequent steps on the device timeline of this.

Device timeline steps:
  1. If pipeline is valid, this.[[device]].[[destroy started]] is true, or this is lost:

    1. Issue the following steps on contentTimeline:

      Content timeline steps:
      1. Resolve promise with pipeline.

    2. Return.

    Note: No errors are generated from a device which is lost or pending destruction. See § 22 Errors & Debugging.

  2. If pipeline is invalid and error is an internal error, issue the following steps on contentTimeline, and return.

  3. If pipeline is invalid and error is a validation error, issue the following steps on contentTimeline, and return.

validating GPURenderPipelineDescriptor(descriptor, layout, device)

Arguments:

Device timeline steps:

  1. Return true if all of the following conditions are satisfied:

validating inter-stage interfaces(device, descriptor)

Arguments:

Returns: boolean

Device timeline steps:

  1. Let maxVertexShaderOutputVariables be device.limits.maxInterStageShaderVariables.

  2. Let maxVertexShaderOutputLocation be device.limits.maxInterStageShaderVariables - 1.

  3. If descriptor.primitive.topology is "point-list":

    1. Decrement maxVertexShaderOutputVariables by 1.

  4. If clip_distances is declared in the output of descriptor.vertex:

    1. Let clipDistancesSize be the array size of clip_distances.

    2. Decrement maxVertexShaderOutputVariables by ceil(clipDistancesSize / 4).

    3. Decrement maxVertexShaderOutputLocation by ceil(clipDistancesSize / 4).

  5. Return false if any of the following requirements are unmet:

    • There must be no more than maxVertexShaderOutputVariables user-defined outputs for descriptor.vertex.

    • The location of each user-defined output of descriptor.vertex must be ≤ maxVertexShaderOutputLocation.

  6. If descriptor.fragment is provided:

    1. Let maxFragmentShaderInputVariables be device.limits.maxInterStageShaderVariables.

    2. If any of the front_facing, sample_index, or sample_mask builtins are an input of descriptor.fragment:

      1. Decrement maxFragmentShaderInputVariables by 1.

    3. Return false if any of the following requirements are unmet:

      • For each user-defined input of descriptor.fragment there must be a user-defined output of descriptor.vertex that location, type, and interpolation of the input.

        Note: Vertex-only pipelines can have user-defined outputs in the vertex stage; their values will be discarded.

      • There must be no more than maxFragmentShaderInputVariables user-defined inputs for descriptor.fragment.

    4. Assert that the location of each user-defined input of descriptor.fragment is less than device.limits.maxInterStageShaderVariables. (This follows from the above rules.)

  7. Return true.

Creating a simple GPURenderPipeline:
const renderPipeline = gpuDevice.createRenderPipeline({
    layout: pipelineLayout,
    vertex: {
        module: shaderModule,
        entryPoint: 'vertexMain'
    },
    fragment: {
        module: shaderModule,
        entryPoint: 'fragmentMain',
        targets: [{
            format: 'bgra8unorm',
        }],
    }
});

10.3.2. Primitive State

dictionary GPUPrimitiveState {
    GPUPrimitiveTopology topology = "triangle-list";
    GPUIndexFormat stripIndexFormat;
    GPUFrontFace frontFace = "ccw";
    GPUCullMode cullMode = "none";

    // Requires "depth-clip-control" feature.
    boolean unclippedDepth = false;
};

GPUPrimitiveState has the following members, which describe how a GPURenderPipeline constructs and rasterizes primitives from its vertex inputs:

topology, of type GPUPrimitiveTopology, defaulting to "triangle-list"

The type of primitive to be constructed from the vertex inputs.

stripIndexFormat, of type GPUIndexFormat

For pipelines with strip topologies ("line-strip" or "triangle-strip"), this determines the index buffer format and primitive restart value ("uint16"/0xFFFF or "uint32"/0xFFFFFFFF). It is not allowed on pipelines with non-strip topologies.

Note: Some implementations require knowledge of the primitive restart value to compile pipeline state objects.

To use a strip-topology pipeline with an indexed draw call (drawIndexed() or drawIndexedIndirect()), this must be set, and it must match the index buffer format used with the draw call (set in setIndexBuffer()).

See § 23.2.3 Primitive Assembly for additional details.

frontFace, of type GPUFrontFace, defaulting to "ccw"

Defines which polygons are considered front-facing.

cullMode, of type GPUCullMode, defaulting to "none"

Defines which polygon orientation will be culled, if any.

unclippedDepth, of type boolean, defaulting to false

If true, indicates that depth clipping is disabled.

Requires the "depth-clip-control" feature to be enabled.

validating GPUPrimitiveState(descriptor, device) Arguments:

Device timeline steps:

  1. Return true if all of the following conditions are satisfied:

enum GPUPrimitiveTopology {
    "point-list",
    "line-list",
    "line-strip",
    "triangle-list",
    "triangle-strip",
};

GPUPrimitiveTopology defines the primitive type draw calls made with a GPURenderPipeline will use. See § 23.2.5 Rasterization for additional details:

"point-list"

Each vertex defines a point primitive.

"line-list"

Each consecutive pair of two vertices defines a line primitive.

"line-strip"

Each vertex after the first defines a line primitive between it and the previous vertex.

"triangle-list"

Each consecutive triplet of three vertices defines a triangle primitive.

"triangle-strip"

Each vertex after the first two defines a triangle primitive between it and the previous two vertices.

enum GPUFrontFace {
    "ccw",
    "cw",
};

GPUFrontFace defines which polygons are considered front-facing by a GPURenderPipeline. See § 23.2.5.4 Polygon Rasterization for additional details:

"ccw"

Polygons with vertices whose framebuffer coordinates are given in counter-clockwise order are considered front-facing.

"cw"

Polygons with vertices whose framebuffer coordinates are given in clockwise order are considered front-facing.

enum GPUCullMode {
    "none",
    "front",
    "back",
};

GPUPrimitiveTopology defines which polygons will be culled by draw calls made with a GPURenderPipeline. See § 23.2.5.4 Polygon Rasterization for additional details:

"none"

No polygons are discarded.

"front"

Front-facing polygons are discarded.

"back"

Back-facing polygons are discarded.

Note: GPUFrontFace and GPUCullMode have no effect on "point-list", "line-list", or "line-strip" topologies.

10.3.3. Multisample State

dictionary GPUMultisampleState {
    GPUSize32 count = 1;
    GPUSampleMask mask = 0xFFFFFFFF;
    boolean alphaToCoverageEnabled = false;
};

GPUMultisampleState has the following members, which describe how a GPURenderPipeline interacts with a render pass’s multisampled attachments.

count, of type GPUSize32, defaulting to 1

Number of samples per pixel. This GPURenderPipeline will be compatible only with attachment textures (colorAttachments and depthStencilAttachment) with matching sampleCounts.

mask, of type GPUSampleMask, defaulting to 0xFFFFFFFF

Mask determining which samples are written to.

alphaToCoverageEnabled, of type boolean, defaulting to false

When true indicates that a fragment’s alpha channel should be used to generate a sample coverage mask.

validating GPUMultisampleState(descriptor) Arguments:

Device timeline steps:

  1. Return true if all of the following conditions are satisfied:

10.3.4. Fragment State

dictionary GPUFragmentState
         : GPUProgrammableStage {
    required sequence<GPUColorTargetState?> targets;
};
targets, of type sequence<GPUColorTargetState?>

A list of GPUColorTargetState defining the formats and behaviors of the color targets this pipeline writes to.

validating GPUFragmentState(device, descriptor, layout)

Arguments:

Device timeline steps:

  1. Return true if all of the following requirements are met:

Validating GPUFragmentState’s color attachment bytes per sample(device, targets)

Arguments:

Device timeline steps:

  1. Let formats be an empty list<GPUTextureFormat?>

  2. For each target in targets:

    1. If target is undefined, continue.

    2. Append target.format to formats.

  3. Calculating color attachment bytes per sample(formats) must be ≤ device.[[limits]].maxColorAttachmentBytesPerSample.

Note: The fragment shader may output more values than what the pipeline uses. If that is the case the values are ignored.

GPUBlendComponent component is a valid GPUBlendComponent with logical device device if it meets
the following requirements:

10.3.5. Color Target State

dictionary GPUColorTargetState {
    required GPUTextureFormat format;

    GPUBlendState blend;
    GPUColorWriteFlags writeMask = 0xF;  // GPUColorWrite.ALL
};
format, of type GPUTextureFormat

The GPUTextureFormat of this color target. The pipeline will only be compatible with GPURenderPassEncoders which use a GPUTextureView of this format in the corresponding color attachment.

blend, of type GPUBlendState

The blending behavior for this color target. If left undefined, disables blending for this color target.

writeMask, of type GPUColorWriteFlags, defaulting to 0xF

Bitmask controlling which channels are are written to when drawing to this color target.

dictionary GPUBlendState {
    required GPUBlendComponent color;
    required GPUBlendComponent alpha;
};
color, of type GPUBlendComponent

Defines the blending behavior of the corresponding render target for color channels.

alpha, of type GPUBlendComponent

Defines the blending behavior of the corresponding render target for the alpha channel.

typedef [EnforceRange] unsigned long GPUColorWriteFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUColorWrite {
    const GPUFlagsConstant RED   = 0x1;
    const GPUFlagsConstant GREEN = 0x2;
    const GPUFlagsConstant BLUE  = 0x4;
    const GPUFlagsConstant ALPHA = 0x8;
    const GPUFlagsConstant ALL   = 0xF;
};
10.3.5.1. Blend State
dictionary GPUBlendComponent {
    GPUBlendOperation operation = "add";
    GPUBlendFactor srcFactor = "one";
    GPUBlendFactor dstFactor = "zero";
};

GPUBlendComponent has the following members, which describe how the color or alpha components of a fragment are blended:

operation, of type GPUBlendOperation, defaulting to "add"

Defines the GPUBlendOperation used to calculate the values written to the target attachment components.

srcFactor, of type GPUBlendFactor, defaulting to "one"

Defines the GPUBlendFactor operation to be performed on values from the fragment shader.

dstFactor, of type GPUBlendFactor, defaulting to "zero"

Defines the GPUBlendFactor operation to be performed on values from the target attachment.

The following tables use this notation to describe color components for a given fragment location:

RGBAsrc Color output by the fragment shader for the color attachment. If the shader doesn’t return an alpha channel, src-alpha blend factors cannot be used.
RGBAsrc1 Color output by the fragment shader for the color attachment with "@blend_src" attribute equal to 1. If the shader doesn’t return an alpha channel, src1-alpha blend factors cannot be used.
RGBAdst Color currently in the color attachment. Missing green/blue/alpha channels default to 0, 0, 1, respectively.
RGBAconst The current [[blendConstant]].
RGBAsrcFactor The source blend factor components, as defined by srcFactor.
RGBAdstFactor The destination blend factor components, as defined by dstFactor.
enum GPUBlendFactor {
    "zero",
    "one",
    "src",
    "one-minus-src",
    "src-alpha",
    "one-minus-src-alpha",
    "dst",
    "one-minus-dst",
    "dst-alpha",
    "one-minus-dst-alpha",
    "src-alpha-saturated",
    "constant",
    "one-minus-constant",
    "src1",
    "one-minus-src1",
    "src1-alpha",
    "one-minus-src1-alpha",
};

GPUBlendFactor defines how either a source or destination blend factors is calculated:

GPUBlendFactor Blend factor RGBA components Feature
"zero" (0, 0, 0, 0)
"one" (1, 1, 1, 1)
"src" (Rsrc, Gsrc, Bsrc, Asrc)
"one-minus-src" (1 - Rsrc, 1 - Gsrc, 1 - Bsrc, 1 - Asrc)
"src-alpha" (Asrc, Asrc, Asrc, Asrc)
"one-minus-src-alpha" (1 - Asrc, 1 - Asrc, 1 - Asrc, 1 - Asrc)
"dst" (Rdst, Gdst, Bdst, Adst)
"one-minus-dst" (1 - Rdst, 1 - Gdst, 1 - Bdst, 1 - Adst)
"dst-alpha" (Adst, Adst, Adst, Adst)
"one-minus-dst-alpha" (1 - Adst, 1 - Adst, 1 - Adst, 1 - Adst)
"src-alpha-saturated" (min(Asrc, 1 - Adst), min(Asrc, 1 - Adst), min(Asrc, 1 - Adst), 1)
"constant" (Rconst, Gconst, Bconst, Aconst)
"one-minus-constant" (1 - Rconst, 1 - Gconst, 1 - Bconst, 1 - Aconst)
"src1" (Rsrc1, Gsrc1, Bsrc1, Asrc1) dual-source-blending
"one-minus-src1" (1 - Rsrc1, 1 - Gsrc1, 1 - Bsrc1, 1 - Asrc1)
"src1-alpha" (Asrc1, Asrc1, Asrc1, Asrc1)
"one-minus-src1-alpha" (1 - Asrc1, 1 - Asrc1, 1 - Asrc1, 1 - Asrc1)
enum GPUBlendOperation {
    "add",
    "subtract",
    "reverse-subtract",
    "min",
    "max",
};

GPUBlendOperation defines the algorithm used to combine source and destination blend factors:

GPUBlendOperation RGBA Components
"add" RGBAsrc × RGBAsrcFactor + RGBAdst × RGBAdstFactor
"subtract" RGBAsrc × RGBAsrcFactor - RGBAdst × RGBAdstFactor
"reverse-subtract" RGBAdst × RGBAdstFactor - RGBAsrc × RGBAsrcFactor
"min" min(RGBAsrc, RGBAdst)
"max" max(RGBAsrc, RGBAdst)

10.3.6. Depth/Stencil State

dictionary GPUDepthStencilState {
    required GPUTextureFormat format;

    boolean depthWriteEnabled;
    GPUCompareFunction depthCompare;

    GPUStencilFaceState stencilFront = {};
    GPUStencilFaceState stencilBack = {};

    GPUStencilValue stencilReadMask = 0xFFFFFFFF;
    GPUStencilValue stencilWriteMask = 0xFFFFFFFF;

    GPUDepthBias depthBias = 0;
    float depthBiasSlopeScale = 0;
    float depthBiasClamp = 0;
};

GPUDepthStencilState has the following members, which describe how a GPURenderPipeline will affect a render pass’s depthStencilAttachment:

format, of type GPUTextureFormat

The format of depthStencilAttachment this GPURenderPipeline will be compatible with.

depthWriteEnabled, of type boolean

Indicates if this GPURenderPipeline can modify depthStencilAttachment depth values.

depthCompare, of type GPUCompareFunction

The comparison operation used to test fragment depths against depthStencilAttachment depth values.

stencilFront, of type GPUStencilFaceState, defaulting to {}

Defines how stencil comparisons and operations are performed for front-facing primitives.

stencilBack, of type GPUStencilFaceState, defaulting to {}

Defines how stencil comparisons and operations are performed for back-facing primitives.

stencilReadMask, of type GPUStencilValue, defaulting to 0xFFFFFFFF

Bitmask controlling which depthStencilAttachment stencil value bits are read when performing stencil comparison tests.

stencilWriteMask, of type GPUStencilValue, defaulting to 0xFFFFFFFF

Bitmask controlling which depthStencilAttachment stencil value bits are written to when performing stencil operations.

depthBias, of type GPUDepthBias, defaulting to 0

Constant depth bias added to each triangle fragment. See biased fragment depth for details.

depthBiasSlopeScale, of type float, defaulting to 0

Depth bias that scales with the triangle fragment’s slope. See biased fragment depth for details.

depthBiasClamp, of type float, defaulting to 0

The maximum depth bias of a triangle fragment. See biased fragment depth for details.

Note: depthBias, depthBiasSlopeScale, and depthBiasClamp have no effect on "point-list", "line-list", and "line-strip" primitives, and must be 0.

The biased fragment depth for a fragment being written to depthStencilAttachment attachment when drawing using GPUDepthStencilState state is calculated by running the following queue timeline steps:
  1. Let format be attachment.view.format.

  2. Let r be the minimum positive representable value > 0 in the format converted to a 32-bit float.

  3. Let maxDepthSlope be the maximum of the horizontal and vertical slopes of the fragment’s depth value.

  4. If format is a unorm format:

    1. Let bias be (float)state.depthBias * r + state.depthBiasSlopeScale * maxDepthSlope.

  5. Otherwise, if format is a float format:

    1. Let bias be (float)state.depthBias * 2^(exp(max depth in primitive) - r) + state.depthBiasSlopeScale * maxDepthSlope.

  6. If state.depthBiasClamp > 0:

    1. Set bias to min(state.depthBiasClamp, bias).

  7. Otherwise if state.depthBiasClamp < 0:

    1. Set bias to max(state.depthBiasClamp, bias).

  8. If state.depthBias0 or state.depthBiasSlopeScale0:

    1. Set the fragment depth value to fragment depth value + bias

validating GPUDepthStencilState(descriptor, topology)

Arguments:

Device timeline steps:

  1. Return true if, and only if, all of the following conditions are satisfied:

dictionary GPUStencilFaceState {
    GPUCompareFunction compare = "always";
    GPUStencilOperation failOp = "keep";
    GPUStencilOperation depthFailOp = "keep";
    GPUStencilOperation passOp = "keep";
};

GPUStencilFaceState has the following members, which describe how stencil comparisons and operations are performed:

compare, of type GPUCompareFunction, defaulting to "always"

The GPUCompareFunction used when testing the [[stencilReference]] value against the fragment’s depthStencilAttachment stencil values.

failOp, of type GPUStencilOperation, defaulting to "keep"

The GPUStencilOperation performed if the fragment stencil comparison test described by compare fails.

depthFailOp, of type GPUStencilOperation, defaulting to "keep"

The GPUStencilOperation performed if the fragment depth comparison described by depthCompare fails.

passOp, of type GPUStencilOperation, defaulting to "keep"

The GPUStencilOperation performed if the fragment stencil comparison test described by compare passes.

enum GPUStencilOperation {
    "keep",
    "zero",
    "replace",
    "invert",
    "increment-clamp",
    "decrement-clamp",
    "increment-wrap",
    "decrement-wrap",
};

GPUStencilOperation defines the following operations:

"keep"

Keep the current stencil value.

"zero"

Set the stencil value to 0.

"replace"

Set the stencil value to [[stencilReference]].

"invert"

Bitwise-invert the current stencil value.

"increment-clamp"

Increments the current stencil value, clamping to the maximum representable value of the depthStencilAttachment's stencil aspect.

"decrement-clamp"

Decrement the current stencil value, clamping to 0.

"increment-wrap"

Increments the current stencil value, wrapping to zero if the value exceeds the maximum representable value of the depthStencilAttachment's stencil aspect.

"decrement-wrap"

Decrement the current stencil value, wrapping to the maximum representable value of the depthStencilAttachment's stencil aspect if the value goes below 0.

10.3.7. Vertex State

enum GPUIndexFormat {
    "uint16",
    "uint32",
};

The index format determines both the data type of index values in a buffer and, when used with strip primitive topologies ("line-strip" or "triangle-strip") also specifies the primitive restart value. The primitive restart value indicates which index value indicates that a new primitive should be started rather than continuing to construct the triangle strip with the prior indexed vertices.

GPUPrimitiveStates that specify a strip primitive topology must specify a stripIndexFormat if they are used for indexed draws so that the primitive restart value that will be used is known at pipeline creation time. GPUPrimitiveStates that specify a list primitive topology will use the index format passed to setIndexBuffer() when doing indexed rendering.

Index format Byte size Primitive restart value
"uint16" 2 0xFFFF
"uint32" 4 0xFFFFFFFF
10.3.7.1. Vertex Formats

The GPUVertexFormat of a vertex attribute indicates how data from a vertex buffer will be interpreted and exposed to the shader. The name of the format specifies the order of components, bits per component, and vertex data type for the component.

Each vertex data type can map to any WGSL scalar type of the same base type, regardless of the bits per component:

Vertex format prefix Vertex data type Compatible WGSL types
uint unsigned int u32
sint signed int i32
unorm unsigned normalized f16, f32
snorm signed normalized
float floating point

The multi-component formats specify the number of components after "x". Mismatches in the number of components between the vertex format and shader type are allowed, with components being either dropped or filled with default values to compensate.

A vertex attribute with a format of "unorm8x2" and byte values [0x7F, 0xFF] can be accessed in the shader with the following types:
Shader type Shader value
f16 0.5h
f32 0.5f
vec2<f16> vec2(0.5h, 1.0h)
vec2<f32> vec2(0.5f, 1.0f)
vec3<f16> vec2(0.5h, 1.0h, 0.0h)
vec3<f32> vec2(0.5f, 1.0f, 0.0f)
vec4<f16> vec2(0.5h, 1.0h, 0.0h, 1.0h)
vec4<f32> vec2(0.5f, 1.0f, 0.0f, 1.0f)

See § 23.2.2 Vertex Processing for additional information about how vertex formats are exposed in the shader.

enum GPUVertexFormat {
    "uint8x2",
    "uint8x4",
    "sint8x2",
    "sint8x4",
    "unorm8x2",
    "unorm8x4",
    "snorm8x2",
    "snorm8x4",
    "uint16x2",
    "uint16x4",
    "sint16x2",
    "sint16x4",
    "unorm16x2",
    "unorm16x4",
    "snorm16x2",
    "snorm16x4",
    "float16x2",
    "float16x4",
    "float32",
    "float32x2",
    "float32x3",
    "float32x4",
    "uint32",
    "uint32x2",
    "uint32x3",
    "uint32x4",
    "sint32",
    "sint32x2",
    "sint32x3",
    "sint32x4",
    "unorm10-10-10-2",
};
Vertex format Data type Components byteSize Example WGSL type
"uint8x2" unsigned int 2 2 vec2<u32>
"uint8x4" unsigned int 4 4 vec4<u32>
"sint8x2" signed int 2 2 vec2<i32>
"sint8x4" signed int 4 4 vec4<i32>
"unorm8x2" unsigned normalized 2 2 vec2<f32>
"unorm8x4" unsigned normalized 4 4 vec4<f32>
"snorm8x2" signed normalized 2 2 vec2<f32>
"snorm8x4" signed normalized 4 4 vec4<f32>
"uint16x2" unsigned int 2 4 vec2<u32>
"uint16x4" unsigned int 4 8 vec4<u32>
"sint16x2" signed int 2 4 vec2<i32>
"sint16x4" signed int 4 8 vec4<i32>
"unorm16x2" unsigned normalized 2 4 vec2<f32>
"unorm16x4" unsigned normalized 4 8 vec4<f32>
"snorm16x2" signed normalized 2 4 vec2<f32>
"snorm16x4" signed normalized 4 8 vec4<f32>
"float16x2" float 2 4 vec2<f16>
"float16x4" float 4 8 vec4<f16>
"float32" float 1 4 f32
"float32x2" float 2 8 vec2<f32>
"float32x3" float 3 12 vec3<f32>
"float32x4" float 4 16 vec4<f32>
"uint32" unsigned int 1 4 u32
"uint32x2" unsigned int 2 8 vec2<u32>
"uint32x3" unsigned int 3 12 vec3<u32>
"uint32x4" unsigned int 4 16 vec4<u32>
"sint32" signed int 1 4 i32
"sint32x2" signed int 2 8 vec2<i32>
"sint32x3" signed int 3 12 vec3<i32>
"sint32x4" signed int 4 16 vec4<i32>
"unorm10-10-10-2" unsigned normalized 4 4 vec4<f32>
enum GPUVertexStepMode {
    "vertex",
    "instance",
};

The step mode configures how an address for vertex buffer data is computed, based on the current vertex or instance index:

"vertex"

The address is advanced by arrayStride for each vertex, and reset between instances.

"instance"

The address is advanced by arrayStride for each instance.

dictionary GPUVertexState
         : GPUProgrammableStage {
    sequence<GPUVertexBufferLayout?> buffers = [];
};
buffers, of type sequence<GPUVertexBufferLayout?>, defaulting to []

A list of GPUVertexBufferLayouts, each defining the layout of vertex attribute data in a vertex buffer used by this pipeline.

A vertex buffer is, conceptually, a view into buffer memory as an array of structures. arrayStride is the stride, in bytes, between elements of that array. Each element of a vertex buffer is like a structure with a memory layout defined by its attributes, which describe the members of the structure.

Each GPUVertexAttribute describes its format and its offset, in bytes, within the structure.

Each attribute appears as a separate input in a vertex shader, each bound by a numeric location, which is specified by shaderLocation. Every location must be unique within the GPUVertexState.

dictionary GPUVertexBufferLayout {
    required GPUSize64 arrayStride;
    GPUVertexStepMode stepMode = "vertex";
    required sequence<GPUVertexAttribute> attributes;
};
arrayStride, of type GPUSize64

The stride, in bytes, between elements of this array.

stepMode, of type GPUVertexStepMode, defaulting to "vertex"

Whether each element of this array represents per-vertex data or per-instance data

attributes, of type sequence<GPUVertexAttribute>

An array defining the layout of the vertex attributes within each element.

dictionary GPUVertexAttribute {
    required GPUVertexFormat format;
    required GPUSize64 offset;

    required GPUIndex32 shaderLocation;
};
format, of type GPUVertexFormat

The GPUVertexFormat of the attribute.

offset, of type GPUSize64

The offset, in bytes, from the beginning of the element to the data for the attribute.

shaderLocation, of type GPUIndex32

The numeric location associated with this attribute, which will correspond with a "@location" attribute declared in the vertex.module.

validating GPUVertexBufferLayout(device, descriptor)

Arguments:

Device timeline steps:

  1. Return true, if and only if, all of the following conditions are satisfied:

validating GPUVertexState(device, descriptor, layout)

Arguments:

Device timeline steps:

  1. Let entryPoint be get the entry point(VERTEX, descriptor).

  2. Assert entryPoint is not null.

  3. All of the requirements in the following steps must be met.

    1. validating GPUProgrammableStage(VERTEX, descriptor, layout, device) must succeed.

    2. descriptor.buffers.size must be ≤ device.[[device]].[[limits]].maxVertexBuffers.

    3. Each vertexBuffer layout descriptor in the list descriptor.buffers must pass validating GPUVertexBufferLayout(device, vertexBuffer).

    4. The sum of vertexBuffer.attributes.size, over every vertexBuffer in descriptor.buffers, must be ≤ device.[[device]].[[limits]].maxVertexAttributes.

    5. For every vertex attribute declaration (at location location with type T) that is statically used by entryPoint, there must be exactly one pair (i, j) for which descriptor.buffers[i]?.attributes[j].shaderLocation == location.

      Let attrib be that GPUVertexAttribute.

    6. T must be compatible with attrib.format's vertex data type:

      "unorm", "snorm", or "float"

      T must be f32 or vecN<f32>.

      "uint"

      T must be u32 or vecN<u32>.

      "sint"

      T must be i32 or vecN<i32>.

11. Copies

11.1. Buffer Copies

Buffer copy operations operate on raw bytes.

WebGPU provides "buffered" GPUCommandEncoder commands:

and "immediate" GPUQueue operations:

11.2. Texel Copies

Texel copy operations operate on texture/"image" data, rather than bytes.

WebGPU provides "buffered" GPUCommandEncoder commands:

and "immediate" GPUQueue operations:

During a texel copy texels are copied over with an equivalent texel representation. Texel copies only guarantee that valid, normal numeric values in the source have the same numeric value in the destination, and may not preserve the bit-representations of the the following values:

Note: Copies may be performed with WGSL shaders, which means that any of the documented WGSL floating point behaviors may be observed.

The following definitions are used by these methods:

11.2.1. GPUTexelCopyBufferLayout

"GPUTexelCopyBufferLayout" describes the "layout" of texels in a "buffer" of bytes (GPUBuffer or AllowSharedBufferSource) in a "texel copy" operation.

dictionary GPUTexelCopyBufferLayout {
    GPUSize64 offset = 0;
    GPUSize32 bytesPerRow;
    GPUSize32 rowsPerImage;
};

A texel image is comprised of one or more rows of texel blocks, referred to here as texel block rows. Each texel block row of a texel image must contain the same number of texel blocks, and all texel blocks in a texel image are of the same GPUTextureFormat.

A GPUTexelCopyBufferLayout is a layout of texel images within some linear memory. It’s used when copying data between a texture and a GPUBuffer, or when scheduling a write into a texture from the GPUQueue.

Operations that copy between byte arrays and textures always operate on whole texel block. It’s not possible to update only a part of a texel block.

Texel blocks are tightly packed within each texel block row in the linear memory layout of a texel copy, with each subsequent texel block immediately following the previous texel block, with no padding. This includes copies to/from specific aspects of depth-or-stencil format textures: stencil values are tightly packed in an array of bytes; depth values are tightly packed in an array of the appropriate type ("depth16unorm" or "depth32float").

offset, of type GPUSize64, defaulting to 0

The offset, in bytes, from the beginning of the texel data source (such as a GPUTexelCopyBufferInfo.buffer) to the start of the texel data within that source.

bytesPerRow, of type GPUSize32

The stride, in bytes, between the beginning of each texel block row and the subsequent texel block row.

Required if there are multiple texel block rows (i.e. the copy height or depth is more than one block).

rowsPerImage, of type GPUSize32

Number of texel block rows per single texel image of the texture. rowsPerImage × bytesPerRow is the stride, in bytes, between the beginning of each texel image of data and the subsequent texel image.

Required if there are multiple texel images (i.e. the copy depth is more than one).

11.2.2. GPUTexelCopyBufferInfo

"GPUTexelCopyBufferInfo" describes the "info" (GPUBuffer and GPUTexelCopyBufferLayout) about a "buffer" source or destination of a "texel copy" operation. Together with the copySize, it describes the footprint of a region of texels in a GPUBuffer.

dictionary GPUTexelCopyBufferInfo
         : GPUTexelCopyBufferLayout {
    required GPUBuffer buffer;
};
buffer, of type GPUBuffer

A buffer which either contains texel data to be copied or will store the texel data being copied, depending on the method it is being passed to.

validating GPUTexelCopyBufferInfo

Arguments:

Returns: boolean

Device timeline steps:

  1. Return true if and only if all of the following conditions are satisfied:

11.2.3. GPUTexelCopyTextureInfo

"GPUTexelCopyTextureInfo" describes the "info" (GPUTexture, etc.) about a "texture" source or destination of a "texel copy" operation. Together with the copySize, it describes a sub-region of a texture (spanning one or more contiguous texture subresources at the same mip-map level).

dictionary GPUTexelCopyTextureInfo {
    required GPUTexture texture;
    GPUIntegerCoordinate mipLevel = 0;
    GPUOrigin3D origin = {};
    GPUTextureAspect aspect = "all";
};
texture, of type GPUTexture

Texture to copy to/from.

mipLevel, of type GPUIntegerCoordinate, defaulting to 0

Mip-map level of the texture to copy to/from.

origin, of type GPUOrigin3D, defaulting to {}

Defines the origin of the copy - the minimum corner of the texture sub-region to copy to/from. Together with copySize, defines the full copy sub-region.

aspect, of type GPUTextureAspect, defaulting to "all"

Defines which aspects of the texture to copy to/from.

The texture copy sub-region for depth slice or array layer index of GPUTexelCopyTextureInfo copyTexture is determined by running the following steps:
  1. Let texture be copyTexture.texture.

  2. If texture.dimension is:

    1d
    1. Assert index is 0

    2. Let depthSliceOrLayer be texture

    2d

    Let depthSliceOrLayer be array layer index of texture

    3d

    Let depthSliceOrLayer be depth slice index of texture

  3. Let textureMip be mip level copyTexture.mipLevel of depthSliceOrLayer.

  4. Return aspect copyTexture.aspect of textureMip.

The texel block byte offset of data described by GPUTexelCopyBufferLayout bufferLayout corresponding to texel block x, y of depth slice or array layer z of a GPUTexture texture is determined by running the following steps:
  1. Let blockBytes be the texel block copy footprint of texture.format.

  2. Let imageOffset be (z × bufferLayout.rowsPerImage × bufferLayout.bytesPerRow) + bufferLayout.offset.

  3. Let rowOffset be (y × bufferLayout.bytesPerRow) + imageOffset.

  4. Let blockOffset be (x × blockBytes) + rowOffset.

  5. Return blockOffset.

validating GPUTexelCopyTextureInfo(texelCopyTextureInfo, copySize)

Arguments:

Returns: boolean

Device timeline steps:

  1. Let blockWidth be the texel block width of texelCopyTextureInfo.texture.format.

  2. Let blockHeight be the texel block height of texelCopyTextureInfo.texture.format.

  3. Return true if and only if all of the following conditions apply:

validating texture buffer copy(texelCopyTextureInfo, bufferLayout, dataLength, copySize, textureUsage, aligned)

Arguments:

Returns: boolean

Device timeline steps:

  1. Let texture be texelCopyTextureInfo.texture

  2. Let aspectSpecificFormat = texture.format.

  3. Let offsetAlignment = texel block copy footprint of texture.format.

  4. Return true if and only if all of the following conditions apply:

    1. validating GPUTexelCopyTextureInfo(texelCopyTextureInfo, copySize) returns true.

    2. texture.sampleCount is 1.

    3. texture.usage contains textureUsage.

    4. If texture.format is a depth-or-stencil format format:

      1. texelCopyTextureInfo.aspect must refer to a single aspect of texture.format.

      2. If textureUsage is:

        COPY_SRC

        That aspect must be a valid texel copy source according to § 26.1.2 Depth-stencil formats.

        COPY_DST

        That aspect must be a valid texel copy destination according to § 26.1.2 Depth-stencil formats.

      3. Set aspectSpecificFormat to the aspect-specific format according to § 26.1.2 Depth-stencil formats.

      4. Set offsetAlignment to 4.

    5. If aligned is true:

      1. bufferLayout.offset is a multiple of offsetAlignment.

    6. validating linear texture data(bufferLayout, dataLength, aspectSpecificFormat, copySize) succeeds.

11.2.4. GPUCopyExternalImageDestInfo

WebGPU textures hold raw numeric data, and are not tagged with semantic metadata describing colors. However, copyExternalImageToTexture() copies from sources that describe colors.

"GPUCopyExternalImageDestInfo" describes the "info" about the "destination" of a "copyExternalImageToTexture()" operation. It is a GPUTexelCopyTextureInfo which is additionally tagged with color space/encoding and alpha-premultiplication metadata, so that semantic color data may be preserved during copies. This metadata affects only the semantics of the copy operation operation, not the state or semantics of the destination texture object.

dictionary GPUCopyExternalImageDestInfo
         : GPUTexelCopyTextureInfo {
    PredefinedColorSpace colorSpace = "srgb";
    boolean premultipliedAlpha = false;
};
colorSpace, of type PredefinedColorSpace, defaulting to "srgb"

Describes the color space and encoding used to encode data into the destination texture.

This may result in values outside of the range [0, 1] being written to the target texture, if its format can represent them. Otherwise, the results are clamped to the target texture format’s range.

Note: If colorSpace matches the source image, conversion may not be necessary. See § 3.10.2 Color Space Conversion Elision.

premultipliedAlpha, of type boolean, defaulting to false

Describes whether the data written into the texture should have its RGB channels premultiplied by the alpha channel, or not.

If this option is set to true and the source is also premultiplied, the source RGB values must be preserved even if they exceed their corresponding alpha values.

Note: If premultipliedAlpha matches the source image, conversion may not be necessary. See § 3.10.2 Color Space Conversion Elision.

11.2.5. GPUCopyExternalImageSourceInfo

"GPUCopyExternalImageSourceInfo" describes the "info" about the "source" of a "copyExternalImageToTexture()" operation.

typedef (ImageBitmap or
         ImageData or
         HTMLImageElement or
         HTMLVideoElement or
         VideoFrame or
         HTMLCanvasElement or
         OffscreenCanvas) GPUCopyExternalImageSource;

dictionary GPUCopyExternalImageSourceInfo {
    required GPUCopyExternalImageSource source;
    GPUOrigin2D origin = {};
    boolean flipY = false;
};

GPUCopyExternalImageSourceInfo has the following members:

source, of type GPUCopyExternalImageSource

The source of the texel copy. The copy source data is captured at the moment that copyExternalImageToTexture() is issued. Source size is determined as described by the external source dimensions table.

origin, of type GPUOrigin2D, defaulting to {}

Defines the origin of the copy - the minimum (top-left) corner of the source sub-region to copy from. Together with copySize, defines the full copy sub-region.

flipY, of type boolean, defaulting to false

Describes whether the source image is vertically flipped, or not.

If this option is set to true, the copy is flipped vertically: the bottom row of the source region is copied into the first row of the destination region, and so on. The origin option is still relative to the top-left corner of the source image, increasing downward.

When external sources are used when creating or copying to textures, the external source dimensions are defined by the source type, given by this table:

External Source type Dimensions
ImageBitmap ImageBitmap.width, ImageBitmap.height
HTMLImageElement HTMLImageElement.naturalWidth, HTMLImageElement.naturalHeight
HTMLVideoElement intrinsic width of the frame, intrinsic height of the frame
VideoFrame VideoFrame.displayWidth, VideoFrame.displayHeight
ImageData ImageData.width, ImageData.height
HTMLCanvasElement or OffscreenCanvas with CanvasRenderingContext2D or GPUCanvasContext HTMLCanvasElement.width, HTMLCanvasElement.height
HTMLCanvasElement or OffscreenCanvas with WebGLRenderingContextBase WebGLRenderingContextBase.drawingBufferWidth, WebGLRenderingContextBase.drawingBufferHeight
HTMLCanvasElement or OffscreenCanvas with ImageBitmapRenderingContext ImageBitmapRenderingContext's internal output bitmap ImageBitmap.width, ImageBitmap.height

11.2.6. Subroutines

GPUTexelCopyTextureInfo physical subresource size

Arguments:

Returns: GPUExtent3D

The GPUTexelCopyTextureInfo physical subresource size of texelCopyTextureInfo is calculated as follows:

Its width, height and depthOrArrayLayers are the width, height, and depth, respectively, of the physical miplevel-specific texture extent of texelCopyTextureInfo.texture subresource at mipmap level texelCopyTextureInfo.mipLevel.

validating linear texture data(layout, byteSize, format, copyExtent)

Arguments:

GPUTexelCopyBufferLayout layout

Layout of the linear texture data.

GPUSize64 byteSize

Total size of the linear data, in bytes.

GPUTextureFormat format

Format of the texture.

GPUExtent3D copyExtent

Extent of the texture to copy.

Device timeline steps:

  1. Let:

  2. Fail if the following input validation requirements are not met:

  3. Let:

    Note: These default values have no effect, as they’re always multiplied by 0.

  4. Let requiredBytesInCopy be 0.

  5. If copyExtent.depthOrArrayLayers > 0:

    1. Increment requiredBytesInCopy by bytesPerRow × rowsPerImage × (copyExtent.depthOrArrayLayers − 1).

    2. If heightInBlocks > 0:

      1. Increment requiredBytesInCopy by bytesPerRow × (heightInBlocks − 1) + bytesInLastRow.

  6. Fail if the following condition is not satisfied:

    • The layout fits inside the linear data: layout.offset + requiredBytesInCopybyteSize.

validating texture copy range

Arguments:

GPUTexelCopyTextureInfo texelCopyTextureInfo

The texture subresource being copied into and copy origin.

GPUExtent3D copySize

The size of the texture.

Device timeline steps:

  1. Let blockWidth be the texel block width of texelCopyTextureInfo.texture.format.

  2. Let blockHeight be the texel block height of texelCopyTextureInfo.texture.format.

  3. Let subresourceSize be the GPUTexelCopyTextureInfo physical subresource size of texelCopyTextureInfo.

  4. Return whether all the conditions below are satisfied:

    Note: The texture copy range is validated against the physical (rounded-up) size for compressed formats, allowing copies to access texture blocks which are not fully inside the texture.

Two GPUTextureFormats format1 and format2 are copy-compatible if:
The set of subresources for texture copy(texelCopyTextureInfo, copySize) is the subset of subresources of texture = texelCopyTextureInfo.texture for which each subresource s satisfies the following:

12. Command Buffers

Command buffers are pre-recorded lists of GPU commands (blocks of queue timeline steps) that can be submitted to a GPUQueue for execution. Each GPU command represents a task to be performed on the queue timeline, such as setting state, drawing, copying resources, etc.

A GPUCommandBuffer can only be submitted once, at which point it becomes invalidated. To reuse rendering commands across multiple submissions, use GPURenderBundle.

12.1. GPUCommandBuffer

[Exposed=(Window, Worker), SecureContext]
interface GPUCommandBuffer {
};
GPUCommandBuffer includes GPUObjectBase;

GPUCommandBuffer has the following device timeline properties:

[[command_list]], of type list<GPU command>, readonly

A list of GPU commands to be executed on the Queue timeline when this command buffer is submitted.

[[renderState]], of type RenderState, initially null

The current state used by any render pass commands being executed.

12.1.1. Command Buffer Creation

dictionary GPUCommandBufferDescriptor
         : GPUObjectDescriptorBase {
};

13. Command Encoding

13.1. GPUCommandsMixin

GPUCommandsMixin defines state common to all interfaces which encode commands. It has no methods.

interface mixin GPUCommandsMixin {
};

GPUCommandsMixin has the following device timeline properties:

[[state]], of type encoder state, initially "open"

The current state of the encoder.

[[commands]], of type list<GPU command>, initially []

A list of GPU commands to be executed on the Queue timeline when a GPUCommandBuffer containing these commands is submitted.

The encoder state may be one of the following:

"open"

The encoder is available to encode new commands.

"locked"

The encoder cannot be used, because it is locked by a child encoder: it is a GPUCommandEncoder, and a GPURenderPassEncoder or GPUComputePassEncoder is active. The encoder becomes "open" again when the pass is ended.

Any command issued in this state invalidates the encoder.

"ended"

The encoder has been ended and new commands can no longer be encoded.

Any command issued in this state will generate a validation error.

To Validate the encoder state of GPUCommandsMixin encoder run the
following device timeline steps:
  1. If encoder.[[state]] is:

    "open"

    Return true.

    "locked"

    Invalidate encoder and return false.

    "ended"

    Generate a validation error, and return false.

To Enqueue a command on GPUCommandsMixin encoder which issues the steps of a GPU Command command, run the following device timeline steps:
  1. Append command to encoder.[[commands]].

  2. When command is executed as part of a GPUCommandBuffer:

    1. Issue the steps of command.

13.2. GPUCommandEncoder

[Exposed=(Window, Worker), SecureContext]
interface GPUCommandEncoder {
    GPURenderPassEncoder beginRenderPass(GPURenderPassDescriptor descriptor);
    GPUComputePassEncoder beginComputePass(optional GPUComputePassDescriptor descriptor = {});

    undefined copyBufferToBuffer(
        GPUBuffer source,
        GPUSize64 sourceOffset,
        GPUBuffer destination,
        GPUSize64 destinationOffset,
        GPUSize64 size);

    undefined copyBufferToTexture(
        GPUTexelCopyBufferInfo source,
        GPUTexelCopyTextureInfo destination,
        GPUExtent3D copySize);

    undefined copyTextureToBuffer(
        GPUTexelCopyTextureInfo source,
        GPUTexelCopyBufferInfo destination,
        GPUExtent3D copySize);

    undefined copyTextureToTexture(
        GPUTexelCopyTextureInfo source,
        GPUTexelCopyTextureInfo destination,
        GPUExtent3D copySize);

    undefined clearBuffer(
        GPUBuffer buffer,
        optional GPUSize64 offset = 0,
        optional GPUSize64 size);

    undefined resolveQuerySet(
        GPUQuerySet querySet,
        GPUSize32 firstQuery,
        GPUSize32 queryCount,
        GPUBuffer destination,
        GPUSize64 destinationOffset);

    GPUCommandBuffer finish(optional GPUCommandBufferDescriptor descriptor = {});
};
GPUCommandEncoder includes GPUObjectBase;
GPUCommandEncoder includes GPUCommandsMixin;
GPUCommandEncoder includes GPUDebugCommandsMixin;

13.2.1. Command Encoder Creation

dictionary GPUCommandEncoderDescriptor
         : GPUObjectDescriptorBase {
};
createCommandEncoder(descriptor)

Creates a GPUCommandEncoder.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createCommandEncoder(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUCommandEncoderDescriptor Description of the GPUCommandEncoder to create.

Returns: GPUCommandEncoder

Content timeline steps:

  1. Let e be ! create a new WebGPU object(this, GPUCommandEncoder, descriptor).

  2. Issue the initialization steps on the Device timeline of this.

  3. Return e.

Device timeline initialization steps:
  1. If any of the following conditions are unsatisfied generate a validation error, invalidate e and return.

    • this must not be lost.

Creating a GPUCommandEncoder, encoding a command to clear a buffer, finishing the encoder to get a GPUCommandBuffer, then submitting it to the GPUQueue.
const commandEncoder = gpuDevice.createCommandEncoder();
commandEncoder.clearBuffer(buffer);
const commandBuffer = commandEncoder.finish();
gpuDevice.queue.submit([commandBuffer]);

13.3. Pass Encoding

beginRenderPass(descriptor)

Begins encoding a render pass described by descriptor.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.beginRenderPass(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPURenderPassDescriptor Description of the GPURenderPassEncoder to create.

Returns: GPURenderPassEncoder

Content timeline steps:

  1. For each non-null colorAttachment in descriptor.colorAttachments:

    1. If colorAttachment.clearValue is provided:

      1. ? validate GPUColor shape(colorAttachment.clearValue).

  2. Let pass be a new GPURenderPassEncoder object.

  3. Issue the initialization steps on the Device timeline of this.

  4. Return pass.

Device timeline initialization steps:
  1. Validate the encoder state of this. If it returns false, invalidate pass and return.

  2. Set this.[[state]] to "locked".

  3. Let attachmentRegions be a list of [texture subresource, depthSlice?] pairs, initially empty. Each pair describes the region of the texture to be rendered to, which includes a single depth slice for "3d" textures only.

  4. For each non-null colorAttachment in descriptor.colorAttachments:

    1. Add [colorAttachment.view, colorAttachment.depthSlice ?? null] to attachmentRegions.

    2. If colorAttachment.resolveTarget is not null:

      1. Add [colorAttachment.resolveTarget, undefined] to attachmentRegions.

  5. If any of the following requirements are unmet, invalidate pass and return.

    • descriptor must meet the Valid Usage rules given device this.[[device]].

    • The set of texture regions in attachmentRegions must be pairwise disjoint. That is, no two texture regions may overlap.

  6. Add each texture subresource in attachmentRegions to pass.[[usage scope]] with usage attachment.

  7. Let depthStencilAttachment be descriptor.depthStencilAttachment.

  8. If depthStencilAttachment is not null:

    1. Let depthStencilView be depthStencilAttachment.view.

    2. Add the depth subresource of depthStencilView, if any, to pass.[[usage scope]] with usage attachment-read if depthStencilAttachment.depthReadOnly is true, or attachment otherwise.

    3. Add the stencil subresource of depthStencilView, if any, to pass.[[usage scope]] with usage attachment-read if depthStencilAttachment.stencilReadOnly is true, or attachment otherwise.

    4. Set pass.[[depthReadOnly]] to depthStencilAttachment.depthReadOnly.

    5. Set pass.[[stencilReadOnly]] to depthStencilAttachment.stencilReadOnly.

  9. Set pass.[[layout]] to derive render targets layout from pass(descriptor).

  10. If descriptor.timestampWrites is provided:

    1. Let timestampWrites be descriptor.timestampWrites.

    2. If timestampWrites.beginningOfPassWriteIndex is provided, append a GPU command to this.[[commands]] with the following steps:

      1. Before the pass commands begin executing, write the current queue timestamp into index timestampWrites.beginningOfPassWriteIndex of timestampWrites.querySet.

    3. If timestampWrites.endOfPassWriteIndex is provided, set pass.[[endTimestampWrite]] to a GPU command with the following steps:

      1. After the pass commands finish executing, write the current queue timestamp into index timestampWrites.endOfPassWriteIndex of timestampWrites.querySet.

  11. Set pass.[[drawCount]] to 0.

  12. Set pass.[[maxDrawCount]] to descriptor.maxDrawCount.

  13. Set pass.[[maxDrawCount]] to descriptor.maxDrawCount.

  14. Enqueue a command on this which issues the subsequent steps on the Queue timeline when executed.

Queue timeline steps:
  1. Let the [[renderState]] of the currently executing GPUCommandBuffer be a new RenderState.

  2. Set [[renderState]].[[colorAttachments]] to descriptor.colorAttachments.

  3. Set [[renderState]].[[depthStencilAttachment]] to descriptor.depthStencilAttachment.

  4. For each non-null colorAttachment in descriptor.colorAttachments:

    1. Let colorView be colorAttachment.view.

    2. If colorView.[[descriptor]].dimension is:

      "3d"

      Let colorSubregion be colorAttachment.depthSlice of colorView.

      Otherwise

      Let colorSubregion be colorView.

    3. If colorAttachment.loadOp is:

      "load"

      Ensure the contents of colorSubregion are loaded into the framebuffer memory associated with colorSubregion.

      "clear"

      Set every texel of the framebuffer memory associated with colorSubregion to colorAttachment.clearValue.

  5. If depthStencilAttachment is not null:

    1. If depthStencilAttachment.depthLoadOp is:

      Not provided

      Assert that depthStencilAttachment.depthReadOnly is true and ensure the contents of the depth subresource of depthStencilView are loaded into the framebuffer memory associated with depthStencilView.

      "load"

      Ensure the contents of the depth subresource of depthStencilView are loaded into the framebuffer memory associated with depthStencilView.

      "clear"

      Set every texel of the framebuffer memory associated with the depth subresource of depthStencilView to depthStencilAttachment.depthClearValue.

    2. If depthStencilAttachment.stencilLoadOp is:

      Not provided

      Assert that depthStencilAttachment.stencilReadOnly is true and ensure the contents of the stencil subresource of depthStencilView are loaded into the framebuffer memory associated with depthStencilView.

      "load"

      Ensure the contents of the stencil subresource of depthStencilView are loaded into the framebuffer memory associated with depthStencilView.

      "clear"

      Set every texel of the framebuffer memory associated with the stencil subresource depthStencilView to depthStencilAttachment.stencilClearValue.

Note: Read-only depth-stencil attachments are implicitly treated as though the "load" operation was used. Validation that requires the load op to not be provided for read-only attachments is done in GPURenderPassDepthStencilAttachment Valid Usage.

beginComputePass(descriptor)

Begins encoding a compute pass described by descriptor.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.beginComputePass(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUComputePassDescriptor

Returns: GPUComputePassEncoder

Content timeline steps:

  1. Let pass be a new GPUComputePassEncoder object.

  2. Issue the initialization steps on the Device timeline of this.

  3. Return pass.

Device timeline initialization steps:
  1. Validate the encoder state of this. If it returns false, invalidate pass and return.

  2. Set this.[[state]] to "locked".

  3. If any of the following requirements are unmet, invalidate pass and return.

  4. If descriptor.timestampWrites is provided:

    1. Let timestampWrites be descriptor.timestampWrites.

    2. If timestampWrites.beginningOfPassWriteIndex is provided, append a GPU command to this.[[commands]] with the following steps:

      1. Before the pass commands begin executing, write the current queue timestamp into index timestampWrites.beginningOfPassWriteIndex of timestampWrites.querySet.

    3. If timestampWrites.endOfPassWriteIndex is provided, set pass.[[endTimestampWrite]] to a GPU command with the following steps:

      1. After the pass commands finish executing, write the current queue timestamp into index timestampWrites.endOfPassWriteIndex of timestampWrites.querySet.

13.4. Buffer Copy Commands

copyBufferToBuffer(source, sourceOffset, destination, destinationOffset, size)

Encode a command into the GPUCommandEncoder that copies data from a sub-region of a GPUBuffer to a sub-region of another GPUBuffer.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.copyBufferToBuffer(source, sourceOffset, destination, destinationOffset, size) method.
Parameter Type Nullable Optional Description
source GPUBuffer The GPUBuffer to copy from.
sourceOffset GPUSize64 Offset in bytes into source to begin copying from.
destination GPUBuffer The GPUBuffer to copy to.
destinationOffset GPUSize64 Offset in bytes into destination to place the copied data.
size GPUSize64 Bytes to copy.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Enqueue a command on this which issues the subsequent steps on the Queue timeline when executed.

Queue timeline steps:
  1. Copy size bytes of source, beginning at sourceOffset, into destination, beginning at destinationOffset.

clearBuffer(buffer, offset, size)

Encode a command into the GPUCommandEncoder that fills a sub-region of a GPUBuffer with zeros.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.clearBuffer(buffer, offset, size) method.
Parameter Type Nullable Optional Description
buffer GPUBuffer The GPUBuffer to clear.
offset GPUSize64 Offset in bytes into buffer where the sub-region to clear begins.
size GPUSize64 Size in bytes of the sub-region to clear. Defaults to the size of the buffer minus offset.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If size is missing, set size to max(0, buffer.size - offset).

  3. If any of the following conditions are unsatisfied, invalidate this and return.

  4. Enqueue a command on this which issues the subsequent steps on the Queue timeline when executed.

Queue timeline steps:
  1. Set size bytes of buffer to 0 starting at offset.

13.5. Texel Copy Commands

copyBufferToTexture(source, destination, copySize)

Encode a command into the GPUCommandEncoder that copies data from a sub-region of a GPUBuffer to a sub-region of one or multiple continuous texture subresources.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.copyBufferToTexture(source, destination, copySize) method.
Parameter Type Nullable Optional Description
source GPUTexelCopyBufferInfo Combined with copySize, defines the region of the source buffer.
destination GPUTexelCopyTextureInfo Combined with copySize, defines the region of the destination texture subresource.
copySize GPUExtent3D

Returns: undefined

Content timeline steps:

  1. ? validate GPUOrigin3D shape(destination.origin).

  2. ? validate GPUExtent3D shape(copySize).

  3. Issue the subsequent steps on the Device timeline of this.[[device]]:

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Let aligned be true.

  3. Let dataLength be source.buffer.size.

  4. If any of the following conditions are unsatisfied, invalidate this and return.

  5. Enqueue a command on this which issues the subsequent steps on the Queue timeline when executed.

Queue timeline steps:
  1. Let blockWidth be the texel block width of destination.texture.

  2. Let blockHeight be the texel block height of destination.texture.

  3. Let dstOrigin be destination.origin.

  4. Let dstBlockOriginX be (dstOrigin.x ÷ blockWidth).

  5. Let dstBlockOriginY be (dstOrigin.y ÷ blockHeight).

  6. Let blockColumns be (copySize.width ÷ blockWidth).

  7. Let blockRows be (copySize.height ÷ blockHeight).

  8. Assert that dstBlockOriginX, dstBlockOriginY, blockColumns, and blockRows are integers.

  9. For each z in the range [0, copySize.depthOrArrayLayers − 1]:

    1. Let dstSubregion be texture copy sub-region (z + dstOrigin.z) of destination.

    2. For each y in the range [0, blockRows − 1]:

      1. For each x in the range [0, blockColumns − 1]:

        1. Let blockOffset be the texel block byte offset of source for (x, y, z) of destination.texture.

        2. Set texel block (dstBlockOriginX + x, dstBlockOriginY + y) of dstSubregion to be an equivalent texel representation to the texel block described by source.buffer at offset blockOffset.

copyTextureToBuffer(source, destination, copySize)

Encode a command into the GPUCommandEncoder that copies data from a sub-region of one or multiple continuous texture subresources to a sub-region of a GPUBuffer.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.copyTextureToBuffer(source, destination, copySize) method.
Parameter Type Nullable Optional Description
source GPUTexelCopyTextureInfo Combined with copySize, defines the region of the source texture subresources.
destination GPUTexelCopyBufferInfo Combined with copySize, defines the region of the destination buffer.
copySize GPUExtent3D

Returns: undefined

Content timeline steps:

  1. ? validate GPUOrigin3D shape(source.origin).

  2. ? validate GPUExtent3D shape(copySize).

  3. Issue the subsequent steps on the Device timeline of this.[[device]]:

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Let aligned be true.

  3. Let dataLength be destination.buffer.size.

  4. If any of the following conditions are unsatisfied, invalidate this and return.

  5. Enqueue a command on this which issues the subsequent steps on the Queue timeline when executed.

Queue timeline steps:
  1. Let blockWidth be the texel block width of source.texture.

  2. Let blockHeight be the texel block height of source.texture.

  3. Let srcOrigin be source.origin.

  4. Let srcBlockOriginX be (srcOrigin.x ÷ blockWidth).

  5. Let srcBlockOriginY be (srcOrigin.y ÷ blockHeight).

  6. Let blockColumns be (copySize.width ÷ blockWidth).

  7. Let blockRows be (copySize.height ÷ blockHeight).

  8. Assert that srcBlockOriginX, srcBlockOriginY, blockColumns, and blockRows are integers.

  9. For each z in the range [0, copySize.depthOrArrayLayers − 1]:

    1. Let srcSubregion be texture copy sub-region (z + srcOrigin.z) of source.

    2. For each y in the range [0, blockRows − 1]:

      1. For each x in the range [0, blockColumns − 1]:

        1. Let blockOffset be the texel block byte offset of destination for (x, y, z) of source.texture.

        2. Set destination.buffer at offset blockOffset to be an equivalent texel representation to texel block (srcBlockOriginX + x, srcBlockOriginY + y) of srcSubregion.

copyTextureToTexture(source, destination, copySize)

Encode a command into the GPUCommandEncoder that copies data from a sub-region of one or multiple contiguous texture subresources to another sub-region of one or multiple continuous texture subresources.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.copyTextureToTexture(source, destination, copySize) method.
Parameter Type Nullable Optional Description
source GPUTexelCopyTextureInfo Combined with copySize, defines the region of the source texture subresources.
destination GPUTexelCopyTextureInfo Combined with copySize, defines the region of the destination texture subresources.
copySize GPUExtent3D

Returns: undefined

Content timeline steps:

  1. ? validate GPUOrigin3D shape(source.origin).

  2. ? validate GPUOrigin3D shape(destination.origin).

  3. ? validate GPUExtent3D shape(copySize).

  4. Issue the subsequent steps on the Device timeline of this.[[device]]:

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Enqueue a command on this which issues the subsequent steps on the Queue timeline when executed.

Queue timeline steps:
  1. Let blockWidth be the texel block width of source.texture.

  2. Let blockHeight be the texel block height of source.texture.

  3. Let srcOrigin be source.origin.

  4. Let srcBlockOriginX be (srcOrigin.x ÷ blockWidth).

  5. Let srcBlockOriginY be (srcOrigin.y ÷ blockHeight).

  6. Let dstOrigin be destination.origin.

  7. Let dstBlockOriginX be (dstOrigin.x ÷ blockWidth).

  8. Let dstBlockOriginY be (dstOrigin.y ÷ blockHeight).

  9. Let blockColumns be (copySize.width ÷ blockWidth).

  10. Let blockRows be (copySize.height ÷ blockHeight).

  11. Assert that srcBlockOriginX, srcBlockOriginY, dstBlockOriginX, dstBlockOriginY, blockColumns, and blockRows are integers.

  12. For each z in the range [0, copySize.depthOrArrayLayers − 1]:

    1. Let srcSubregion be texture copy sub-region (z + srcOrigin.z) of source.

    2. Let dstSubregion be texture copy sub-region (z + dstOrigin.z) of destination.

    3. For each y in the range [0, blockRows − 1]:

      1. For each x in the range [0, blockColumns − 1]:

        1. Set texel block (dstBlockOriginX + x, dstBlockOriginY + y) of dstSubregion to be an equivalent texel representation to texel block (srcBlockOriginX + x, srcBlockOriginY + y) of srcSubregion.

13.6. Queries

resolveQuerySet(querySet, firstQuery, queryCount, destination, destinationOffset)

Resolves query results from a GPUQuerySet out into a range of a GPUBuffer.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.resolveQuerySet(querySet, firstQuery, queryCount, destination, destinationOffset) method.
Parameter Type Nullable Optional Description
querySet GPUQuerySet
firstQuery GPUSize32
queryCount GPUSize32
destination GPUBuffer
destinationOffset GPUSize64

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

    • querySet is valid to use with this.

    • destination is valid to use with this.

    • destination.usage contains QUERY_RESOLVE.

    • firstQuery < the number of queries in querySet.

    • (firstQuery + queryCount) ≤ the number of queries in querySet.

    • destinationOffset is a multiple of 256.

    • destinationOffset + 8 × queryCountdestination.size.

  3. Enqueue a command on this which issues the subsequent steps on the Queue timeline when executed.

Queue timeline steps:
  1. Let queryIndex be firstQuery.

  2. Let offset be destinationOffset.

  3. While queryIndex < firstQuery + queryCount:

    1. Set 8 bytes of destination, beginning at offset, to be the value of querySet at queryIndex.

    2. Set queryIndex to be queryIndex + 1.

    3. Set offset to be offset + 8.

13.7. Finalization

A GPUCommandBuffer containing the commands recorded by the GPUCommandEncoder can be created by calling finish(). Once finish() has been called the command encoder can no longer be used.

finish(descriptor)

Completes recording of the commands sequence and returns a corresponding GPUCommandBuffer.

Called on: GPUCommandEncoder this.

Arguments:

Arguments for the GPUCommandEncoder.finish(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUCommandBufferDescriptor

Returns: GPUCommandBuffer

Content timeline steps:

  1. Let commandBuffer be a new GPUCommandBuffer.

  2. Issue the finish steps on the Device timeline of this.[[device]].

  3. Return commandBuffer.

Device timeline finish steps:
  1. Let validationSucceeded be true if all of the following requirements are met, and false otherwise.

  2. Set this.[[state]] to "ended".

  3. If validationSucceeded is false, then:

    1. Generate a validation error.

    2. Return an invalidated GPUCommandBuffer.

  4. Set commandBuffer.[[command_list]] to this.[[commands]].

14. Programmable Passes

interface mixin GPUBindingCommandsMixin {
    undefined setBindGroup(GPUIndex32 index, GPUBindGroup? bindGroup,
        optional sequence<GPUBufferDynamicOffset> dynamicOffsets = []);

    undefined setBindGroup(GPUIndex32 index, GPUBindGroup? bindGroup,
        Uint32Array dynamicOffsetsData,
        GPUSize64 dynamicOffsetsDataStart,
        GPUSize32 dynamicOffsetsDataLength);
};

GPUBindingCommandsMixin assumes the presence of GPUObjectBase and GPUCommandsMixin members on the same object. It must only be included by interfaces which also include those mixins.

GPUBindingCommandsMixin has the following device timeline properties:

[[bind_groups]], of type ordered map<GPUIndex32, GPUBindGroup>, initially empty

The current GPUBindGroup for each index.

[[dynamic_offsets]], of type ordered map<GPUIndex32, list<GPUBufferDynamicOffset>>, initally empty

The current dynamic offsets for each [[bind_groups]] entry.

14.1. Bind Groups

setBindGroup() has two overloads:

setBindGroup(index, bindGroup, dynamicOffsets)

Sets the current GPUBindGroup for the given index.

Called on: GPUBindingCommandsMixin this.

Arguments:

index, of type GPUIndex32, non-nullable, required

The index to set the bind group at.

bindGroup, of type GPUBindGroup, nullable, required

Bind group to use for subsequent render or compute commands.

dynamicOffsets, of type sequence<GPUBufferDynamicOffset>, non-nullable, defaulting to []

Array containing buffer offsets in bytes for each entry in bindGroup marked as buffer.hasDynamicOffset.

Returns: undefined

Note: dynamicOffsets[i] is used for the i-th dynamic buffer binding in the bind group, when bindings are ordered by GPUBindGroupLayoutEntry.binding. Said differently dynamicOffsets are in the same order as dynamic buffer binding’s GPUBindGroupLayoutEntry.binding.

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Let dynamicOffsetCount be 0 if bindGroup is null, or bindGroup.[[layout]].[[dynamicOffsetCount]] if not.

  3. If any of the following requirements are unmet, invalidate this and return.

  4. If bindGroup is null:

    1. Remove this.[[bind_groups]][index].

    2. Remove this.[[dynamic_offsets]][index].

    Otherwise:

    1. If any of the following requirements are unmet, invalidate this and return.

    2. Set this.[[bind_groups]][index] to be bindGroup.

    3. Set this.[[dynamic_offsets]][index] to be a copy of dynamicOffsets.

    4. If this is a GPURenderCommandsMixin:

      1. For each bindGroup in this.[[bind_groups]], merge bindGroup.[[usedResources]] into this.[[usage scope]]

setBindGroup(index, bindGroup, dynamicOffsetsData, dynamicOffsetsDataStart, dynamicOffsetsDataLength)

Sets the current GPUBindGroup for the given index, specifying dynamic offsets as a subset of a Uint32Array.

Called on: GPUBindingCommandsMixin this.

Arguments:

Arguments for the GPUBindingCommandsMixin.setBindGroup(index, bindGroup, dynamicOffsetsData, dynamicOffsetsDataStart, dynamicOffsetsDataLength) method.
Parameter Type Nullable Optional Description
index GPUIndex32 The index to set the bind group at.
bindGroup GPUBindGroup? Bind group to use for subsequent render or compute commands.
dynamicOffsetsData Uint32Array Array containing buffer offsets in bytes for each entry in bindGroup marked as buffer.hasDynamicOffset.
dynamicOffsetsDataStart GPUSize64 Offset in elements into dynamicOffsetsData where the buffer offset data begins.
dynamicOffsetsDataLength GPUSize32 Number of buffer offsets to read from dynamicOffsetsData.

Returns: undefined

Content timeline steps:

  1. If any of the following requirements are unmet, throw a RangeError and return.

    • dynamicOffsetsDataStart must be ≥ 0.

    • dynamicOffsetsDataStart + dynamicOffsetsDataLength must be ≤ dynamicOffsetsData.length.

  2. Let dynamicOffsets be a list containing the range, starting at index dynamicOffsetsDataStart, of dynamicOffsetsDataLength elements of a copy of dynamicOffsetsData.

  3. Call this.setBindGroup(index, bindGroup, dynamicOffsets).

To Iterate over each dynamic binding offset in a given GPUBindGroup bindGroup with a given list of steps to be executed for each dynamic offset, run the following device timeline steps:
  1. Let dynamicOffsetIndex be 0.

  2. Let layout be bindGroup.[[layout]].

  3. For each GPUBindGroupEntry entry in bindGroup.[[entries]] ordered in increasing values of entry.binding:

    1. Let bindingDescriptor be the GPUBindGroupLayoutEntry at layout.[[entryMap]][entry.binding]:

    2. If bindingDescriptor.buffer?.hasDynamicOffset is true:

      1. Let bufferBinding be entry.resource.

      2. Let bufferLayout be bindingDescriptor.buffer.

      3. Call steps with bufferBinding, bufferLayout, and dynamicOffsetIndex.

      4. Let dynamicOffsetIndex be dynamicOffsetIndex + 1

Validate encoder bind groups(encoder, pipeline)

Arguments:

GPUBindingCommandsMixin encoder

Encoder whose bind groups are being validated.

GPUPipelineBase pipeline

Pipeline to validate encoders bind groups are compatible with.

Device timeline steps:

  1. If any of the following conditions are unsatisfied, return false:

Otherwise return true.

Encoder bind groups alias a writable resource(encoder, pipeline) if any writable buffer binding range overlaps with any other binding range of the same buffer, or any writable texture binding overlaps in texture subresources with any other texture binding (which may use the same or a different GPUTextureView object).

Note: This algorithm limits the use of the usage scope storage exception.

Arguments:

GPUBindingCommandsMixin encoder

Encoder whose bind groups are being validated.

GPUPipelineBase pipeline

Pipeline to validate encoders bind groups are compatible with.

Device timeline steps:

  1. For each stage in [VERTEX, FRAGMENT, COMPUTE]:

    1. Let bufferBindings be a list of (GPUBufferBinding, boolean) pairs, where the latter indicates whether the resource was used as writable.

    2. Let textureViews be a list of (GPUTextureView, boolean) pairs, where the latter indicates whether the resource was used as writable.

    3. For each pair of (GPUIndex32 bindGroupIndex, GPUBindGroupLayout bindGroupLayout) in pipeline.[[layout]].[[bindGroupLayouts]]:

      1. Let bindGroup be encoder.[[bind_groups]][bindGroupIndex].

      2. Let bindGroupLayoutEntries be bindGroupLayout.[[descriptor]].entries.

      3. Let bufferRanges be the bound buffer ranges of bindGroup, given dynamic offsets encoder.[[dynamic_offsets]][bindGroupIndex]

      4. For each (GPUBindGroupLayoutEntry bindGroupLayoutEntry, GPUBufferBinding resource) in bufferRanges, in which bindGroupLayoutEntry.visibility contains stage:

        1. Let resourceWritable be (bindGroupLayoutEntry.buffer.type == "storage").

        2. For each pair (GPUBufferBinding pastResource, boolean pastResourceWritable) in bufferBindings:

          1. If (resourceWritable or pastResourceWritable) is true, and pastResource and resource are buffer-binding-aliasing, return true.

        3. Append (resource, resourceWritable) to bufferBindings.

      5. For each GPUBindGroupLayoutEntry bindGroupLayoutEntry in bindGroupLayoutEntries, and corresponding GPUTextureView resource in bindGroup, in which bindGroupLayoutEntry.visibility contains stage:

        1. If bindGroupLayoutEntry.storageTexture is not provided, continue.

        2. Let resourceWritable be whether bindGroupLayoutEntry.storageTexture.access is a writable access mode.

        3. For each pair (GPUTextureView pastResource, boolean pastResourceWritable) in textureViews,

          1. If (resourceWritable or pastResourceWritable) is true, and pastResource and resource is texture-view-aliasing, return true.

        4. Append (resource, resourceWritable) to textureViews.

  2. Return false.

Note: Implementations are strongly encouraged to optimize this algorithm.

15. Debug Markers

GPUDebugCommandsMixin provides methods to apply debug labels to groups of commands or insert a single label into the command sequence.

Debug groups can be nested to create a hierarchy of labeled commands, and must be well-balanced.

Like object labels, these labels have no required behavior, but may be shown in error messages and browser developer tools, and may be passed to native API backends.

interface mixin GPUDebugCommandsMixin {
    undefined pushDebugGroup(USVString groupLabel);
    undefined popDebugGroup();
    undefined insertDebugMarker(USVString markerLabel);
};

GPUDebugCommandsMixin assumes the presence of GPUObjectBase and GPUCommandsMixin members on the same object. It must only be included by interfaces which also include those mixins.

GPUDebugCommandsMixin has the following device timeline properties:

[[debug_group_stack]], of type stack<USVString>

A stack of active debug group labels.

GPUDebugCommandsMixin has the following methods:

pushDebugGroup(groupLabel)

Begins a labeled debug group containing subsequent commands.

Called on: GPUDebugCommandsMixin this.

Arguments:

Arguments for the GPUDebugCommandsMixin.pushDebugGroup(groupLabel) method.
Parameter Type Nullable Optional Description
groupLabel USVString The label for the command group.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Push groupLabel onto this.[[debug_group_stack]].

popDebugGroup()

Ends the labeled debug group most recently started by pushDebugGroup().

Called on: GPUDebugCommandsMixin this.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following requirements are unmet, invalidate this and return.

  3. Pop an entry off of this.[[debug_group_stack]].

insertDebugMarker(markerLabel)

Marks a point in a stream of commands with a label.

Called on: GPUDebugCommandsMixin this.

Arguments:

Arguments for the GPUDebugCommandsMixin.insertDebugMarker(markerLabel) method.
Parameter Type Nullable Optional Description
markerLabel USVString The label to insert.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

16. Compute Passes

16.1. GPUComputePassEncoder

[Exposed=(Window, Worker), SecureContext]
interface GPUComputePassEncoder {
    undefined setPipeline(GPUComputePipeline pipeline);
    undefined dispatchWorkgroups(GPUSize32 workgroupCountX, optional GPUSize32 workgroupCountY = 1, optional GPUSize32 workgroupCountZ = 1);
    undefined dispatchWorkgroupsIndirect(GPUBuffer indirectBuffer, GPUSize64 indirectOffset);

    undefined end();
};
GPUComputePassEncoder includes GPUObjectBase;
GPUComputePassEncoder includes GPUCommandsMixin;
GPUComputePassEncoder includes GPUDebugCommandsMixin;
GPUComputePassEncoder includes GPUBindingCommandsMixin;

GPUComputePassEncoder has the following device timeline properties:

[[command_encoder]], of type GPUCommandEncoder, readonly

The GPUCommandEncoder that created this compute pass encoder.

[[endTimestampWrite]], of type GPU command?, readonly, defaulting to null

GPU command, if any, writing a timestamp when the pass ends.

[[pipeline]], of type GPUComputePipeline, initially null

The current GPUComputePipeline.

16.1.1. Compute Pass Encoder Creation

dictionary GPUComputePassTimestampWrites {
    required GPUQuerySet querySet;
    GPUSize32 beginningOfPassWriteIndex;
    GPUSize32 endOfPassWriteIndex;
};
querySet, of type GPUQuerySet

The GPUQuerySet, of type "timestamp", that the query results will be written to.

beginningOfPassWriteIndex, of type GPUSize32

If defined, indicates the query index in querySet into which the timestamp at the beginning of the compute pass will be written.

endOfPassWriteIndex, of type GPUSize32

If defined, indicates the query index in querySet into which the timestamp at the end of the compute pass will be written.

Note: Timestamp query values are written in nanoseconds, but how the value is determined is implementation-defined and may not increase monotonically. See § 20.4 Timestamp Query for details.

dictionary GPUComputePassDescriptor
         : GPUObjectDescriptorBase {
    GPUComputePassTimestampWrites timestampWrites;
};
timestampWrites, of type GPUComputePassTimestampWrites

Defines which timestamp values will be written for this pass, and where to write them to.

16.1.2. Dispatch

setPipeline(pipeline)

Sets the current GPUComputePipeline.

Called on: GPUComputePassEncoder this.

Arguments:

Arguments for the GPUComputePassEncoder.setPipeline(pipeline) method.
Parameter Type Nullable Optional Description
pipeline GPUComputePipeline The compute pipeline to use for subsequent dispatch commands.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Set this.[[pipeline]] to be pipeline.

dispatchWorkgroups(workgroupCountX, workgroupCountY, workgroupCountZ)

Dispatch work to be performed with the current GPUComputePipeline. See § 23.1 Computing for the detailed specification.

Called on: GPUComputePassEncoder this.

Arguments:

Arguments for the GPUComputePassEncoder.dispatchWorkgroups(workgroupCountX, workgroupCountY, workgroupCountZ) method.
Parameter Type Nullable Optional Description
workgroupCountX GPUSize32 X dimension of the grid of workgroups to dispatch.
workgroupCountY GPUSize32 Y dimension of the grid of workgroups to dispatch.
workgroupCountZ GPUSize32 Z dimension of the grid of workgroups to dispatch.
NOTE:
The x, y, and z values passed to dispatchWorkgroups() and dispatchWorkgroupsIndirect() are the number of workgroups to dispatch for each dimension, not the number of shader invocations to perform across each dimension. This matches the behavior of modern native GPU APIs, but differs from the behavior of OpenCL.

This means that if a GPUShaderModule defines an entry point with @workgroup_size(4, 4), and work is dispatched to it with the call computePass.dispatchWorkgroups(8, 8); the entry point will be invoked 1024 times total: Dispatching a 4x4 workgroup 8 times along both the X and Y axes. (4*4*8*8=1024)

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Let usageScope be an empty usage scope.

  3. For each bindGroup in this.[[bind_groups]], merge bindGroup.[[usedResources]] into this.[[usage scope]]

  4. If any of the following conditions are unsatisfied, invalidate this and return.

  5. Let bindingState be a snapshot of this’s current state.

  6. Enqueue a command on this which issues the subsequent steps on the Queue timeline.

Queue timeline steps:
  1. Execute a grid of workgroups with dimensions [workgroupCountX, workgroupCountY, workgroupCountZ] with bindingState.[[pipeline]] using bindingState.[[bind_groups]].

dispatchWorkgroupsIndirect(indirectBuffer, indirectOffset)

Dispatch work to be performed with the current GPUComputePipeline using parameters read from a GPUBuffer. See § 23.1 Computing for the detailed specification.

The indirect dispatch parameters encoded in the buffer must be a tightly packed block of three 32-bit unsigned integer values (12 bytes total), given in the same order as the arguments for dispatchWorkgroups(). For example:

let dispatchIndirectParameters = new Uint32Array(3);
dispatchIndirectParameters[0] = workgroupCountX;
dispatchIndirectParameters[1] = workgroupCountY;
dispatchIndirectParameters[2] = workgroupCountZ;
Called on: GPUComputePassEncoder this.

Arguments:

Arguments for the GPUComputePassEncoder.dispatchWorkgroupsIndirect(indirectBuffer, indirectOffset) method.
Parameter Type Nullable Optional Description
indirectBuffer GPUBuffer Buffer containing the indirect dispatch parameters.
indirectOffset GPUSize64 Offset in bytes into indirectBuffer where the dispatch data begins.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Let usageScope be an empty usage scope.

  3. For each bindGroup in this.[[bind_groups]], merge bindGroup.[[usedResources]] into this.[[usage scope]]

  4. Add indirectBuffer to usageScope with usage input.

  5. If any of the following conditions are unsatisfied, invalidate this and return.

  6. Let bindingState be a snapshot of this’s current state.

  7. Enqueue a command on this which issues the subsequent steps on the Queue timeline.

Queue timeline steps:
  1. Let workgroupCountX be an unsigned 32-bit integer read from indirectBuffer at indirectOffset bytes.

  2. Let workgroupCountY be an unsigned 32-bit integer read from indirectBuffer at (indirectOffset + 4) bytes.

  3. Let workgroupCountZ be an unsigned 32-bit integer read from indirectBuffer at (indirectOffset + 8) bytes.

  4. If workgroupCountX, workgroupCountY, or workgroupCountZ is greater than this.device.limits.maxComputeWorkgroupsPerDimension, return.

  5. Execute a grid of workgroups with dimensions [workgroupCountX, workgroupCountY, workgroupCountZ] with bindingState.[[pipeline]] using bindingState.[[bind_groups]].

16.1.3. Finalization

The compute pass encoder can be ended by calling end() once the user has finished recording commands for the pass. Once end() has been called the compute pass encoder can no longer be used.

end()

Completes recording of the compute pass commands sequence.

Called on: GPUComputePassEncoder this.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Let parentEncoder be this.[[command_encoder]].

  2. If any of the following requirements are unmet, generate a validation error and return.

  3. Set this.[[state]] to "ended".

  4. Set parentEncoder.[[state]] to "open".

  5. If any of the following requirements are unmet, invalidate parentEncoder and return.

  6. Extend parentEncoder.[[commands]] with this.[[commands]].

  7. If this.[[endTimestampWrite]] is not null:

    1. Extend parentEncoder.[[commands]] with this.[[endTimestampWrite]].

17. Render Passes

17.1. GPURenderPassEncoder

[Exposed=(Window, Worker), SecureContext]
interface GPURenderPassEncoder {
    undefined setViewport(float x, float y,
        float width, float height,
        float minDepth, float maxDepth);

    undefined setScissorRect(GPUIntegerCoordinate x, GPUIntegerCoordinate y,
                        GPUIntegerCoordinate width, GPUIntegerCoordinate height);

    undefined setBlendConstant(GPUColor color);
    undefined setStencilReference(GPUStencilValue reference);

    undefined beginOcclusionQuery(GPUSize32 queryIndex);
    undefined endOcclusionQuery();

    undefined executeBundles(sequence<GPURenderBundle> bundles);
    undefined end();
};
GPURenderPassEncoder includes GPUObjectBase;
GPURenderPassEncoder includes GPUCommandsMixin;
GPURenderPassEncoder includes GPUDebugCommandsMixin;
GPURenderPassEncoder includes GPUBindingCommandsMixin;
GPURenderPassEncoder includes GPURenderCommandsMixin;

GPURenderPassEncoder has the following device timeline properties:

[[command_encoder]], of type GPUCommandEncoder, readonly

The GPUCommandEncoder that created this render pass encoder.

[[attachment_size]], readonly

Set to the following extents:

  • width, height = the dimensions of the pass’s render attachments

[[occlusion_query_set]], of type GPUQuerySet, readonly

The GPUQuerySet to store occlusion query results for the pass, which is initialized with GPURenderPassDescriptor.occlusionQuerySet at pass creation time.

[[endTimestampWrite]], of type GPU command?, readonly, defaulting to null

GPU command, if any, writing a timestamp when the pass ends.

[[maxDrawCount]] of type GPUSize64, readonly

The maximum number of draws allowed in this pass.

[[occlusion_query_active]], of type boolean

Whether the pass’s [[occlusion_query_set]] is being written.

When executing encoded render pass commands as part of a GPUCommandBuffer, an internal RenderState object is used to track the current state required for rendering.

RenderState has the following queue timeline properties:

[[occlusionQueryIndex]], of type GPUSize32

The index into [[occlusion_query_set]] at which to store the occlusion query results.

[[viewport]]

Current viewport rectangle and depth range. Initially set to the following values:

  • x, y = 0.0, 0.0

  • width, height = the dimensions of the pass’s render targets

  • minDepth, maxDepth = 0.0, 1.0

[[scissorRect]]

Current scissor rectangle. Initially set to the following values:

  • x, y = 0, 0

  • width, height = the dimensions of the pass’s render targets

[[blendConstant]], of type GPUColor

Current blend constant value, initially [0, 0, 0, 0].

[[stencilReference]], of type GPUStencilValue

Current stencil reference value, initially 0.

[[colorAttachments]], of type sequence<GPURenderPassColorAttachment?>

The color attachments and state for this render pass.

[[depthStencilAttachment]], of type GPURenderPassDepthStencilAttachment?

The depth/stencil attachment and state for this render pass.

Render passes also have framebuffer memory, which contains the texel data associated with each attachment that is written into by draw commands and read from for blending and depth/stencil testing.

Note: Depending on the GPU hardware, framebuffer memory may be the memory allocated by the attachment textures or may be a separate area of memory that the texture data is copied to and from, such as with tile-based architectures.

17.1.1. Render Pass Encoder Creation

dictionary GPURenderPassTimestampWrites {
    required GPUQuerySet querySet;
    GPUSize32 beginningOfPassWriteIndex;
    GPUSize32 endOfPassWriteIndex;
};
querySet, of type GPUQuerySet

The GPUQuerySet, of type "timestamp", that the query results will be written to.

beginningOfPassWriteIndex, of type GPUSize32

If defined, indicates the query index in querySet into which the timestamp at the beginning of the render pass will be written.

endOfPassWriteIndex, of type GPUSize32

If defined, indicates the query index in querySet into which the timestamp at the end of the render pass will be written.

Note: Timestamp query values are written in nanoseconds, but how the value is determined is implementation-defined and may not increase monotonically. See § 20.4 Timestamp Query for details.

dictionary GPURenderPassDescriptor
         : GPUObjectDescriptorBase {
    required sequence<GPURenderPassColorAttachment?> colorAttachments;
    GPURenderPassDepthStencilAttachment depthStencilAttachment;
    GPUQuerySet occlusionQuerySet;
    GPURenderPassTimestampWrites timestampWrites;
    GPUSize64 maxDrawCount = 50000000;
};
colorAttachments, of type sequence<GPURenderPassColorAttachment?>

The set of GPURenderPassColorAttachment values in this sequence defines which color attachments will be output to when executing this render pass.

Due to usage compatibility, no color attachment may alias another attachment or any resource used inside the render pass.

depthStencilAttachment, of type GPURenderPassDepthStencilAttachment

The GPURenderPassDepthStencilAttachment value that defines the depth/stencil attachment that will be output to and tested against when executing this render pass.

Due to usage compatibility, no writable depth/stencil attachment may alias another attachment or any resource used inside the render pass.

occlusionQuerySet, of type GPUQuerySet

The GPUQuerySet value defines where the occlusion query results will be stored for this pass.

timestampWrites, of type GPURenderPassTimestampWrites

Defines which timestamp values will be written for this pass, and where to write them to.

maxDrawCount, of type GPUSize64, defaulting to 50000000

The maximum number of draw calls that will be done in the render pass. Used by some implementations to size work injected before the render pass. Keeping the default value is a good default, unless it is known that more draw calls will be done.

Valid Usage

Given a GPUDevice device and GPURenderPassDescriptor this, the following validation rules apply:

  1. this.colorAttachments.size must be ≤ device.[[limits]].maxColorAttachments.

  2. For each non-null colorAttachment in this.colorAttachments:

    1. colorAttachment.view must be valid to use with device.

    2. If colorAttachment.resolveTarget is provided:

      1. colorAttachment.resolveTarget must be valid to use with device.

    3. colorAttachment must meet the GPURenderPassColorAttachment Valid Usage rules.

  3. If this.depthStencilAttachment is provided:

    1. this.depthStencilAttachment.view must be valid to use with device.

    2. this.depthStencilAttachment must meet the GPURenderPassDepthStencilAttachment Valid Usage rules.

  4. There must exist at least one attachment, either:

  5. Validating GPURenderPassDescriptor’s color attachment bytes per sample(device, this.colorAttachments) succeeds.

  6. All views in non-null members of this.colorAttachments, and this.depthStencilAttachment.view if present, must have equal sampleCounts.

  7. For each view in non-null members of this.colorAttachments and this.depthStencilAttachment.view, if present, the [[renderExtent]] must match.

  8. If this.occlusionQuerySet is provided:

    1. this.occlusionQuerySet must be valid to use with device.

    2. this.occlusionQuerySet.type must be occlusion.

  9. If this.timestampWrites is provided:

Validating GPURenderPassDescriptor’s color attachment bytes per sample(device, colorAttachments)

Arguments:

Device timeline steps:

  1. Let formats be an empty list<GPUTextureFormat?>

  2. For each colorAttachment in colorAttachments:

    1. If colorAttachment is undefined, continue.

    2. Append colorAttachment.view.[[descriptor]].format to formats.

  3. Calculating color attachment bytes per sample(formats) must be ≤ device.[[limits]].maxColorAttachmentBytesPerSample.

17.1.1.1. Color Attachments
dictionary GPURenderPassColorAttachment {
    required GPUTextureView view;
    GPUIntegerCoordinate depthSlice;
    GPUTextureView resolveTarget;

    GPUColor clearValue;
    required GPULoadOp loadOp;
    required GPUStoreOp storeOp;
};
view, of type GPUTextureView

A GPUTextureView describing the texture subresource that will be output to for this color attachment.

depthSlice, of type GPUIntegerCoordinate

Indicates the depth slice index of "3d" view that will be output to for this color attachment.

resolveTarget, of type GPUTextureView

A GPUTextureView describing the texture subresource that will receive the resolved output for this color attachment if view is multisampled.

clearValue, of type GPUColor

Indicates the value to clear view to prior to executing the render pass. If not provided, defaults to {r: 0, g: 0, b: 0, a: 0}. Ignored if loadOp is not "clear".

The components of clearValue are all double values. They are converted to a texel value of texture format matching the render attachment. If conversion fails, a validation error is generated.

loadOp, of type GPULoadOp

Indicates the load operation to perform on view prior to executing the render pass.

Note: It is recommended to prefer clearing; see "clear" for details.

storeOp, of type GPUStoreOp

The store operation to perform on view after executing the render pass.

GPURenderPassColorAttachment Valid Usage

Given a GPURenderPassColorAttachment this:

  1. Let renderViewDescriptor be this.view.[[descriptor]].

  2. Let renderTexture be this.view.[[texture]].

  3. All of the requirements in the following steps must be met.

    1. renderViewDescriptor.format must be a color renderable format.

    2. this.view must be a renderable texture view.

    3. If renderViewDescriptor.dimension is "3d":

      1. this.depthSlice must be provided and must be < the depthOrArrayLayers of the logical miplevel-specific texture extent of the renderTexture subresource at mipmap level renderViewDescriptor.baseMipLevel.

      Otherwise:

      1. this.depthSlice must not be provided.

    4. If this.loadOp is "clear":

      1. Converting the IDL value this.clearValue to a texel value of texture format renderViewDescriptor.format must not throw a TypeError.

        Note: An error is not thrown if the value is out-of-range for the format but in-range for the corresponding WGSL primitive type (f32, i32, or u32).

    5. If this.resolveTarget is provided:

      1. Let resolveViewDescriptor be this.resolveTarget.[[descriptor]].

      2. Let resolveTexture be this.resolveTarget.[[texture]].

      3. renderTexture.sampleCount must be > 1.

      4. resolveTexture.sampleCount must be 1.

      5. this.resolveTarget must be a non-3d renderable texture view.

      6. this.resolveTarget.[[renderExtent]] and this.view.[[renderExtent]] must match.

      7. resolveViewDescriptor.format must equal renderViewDescriptor.format.

      8. resolveTexture.format must equal renderTexture.format.

      9. resolveViewDescriptor.format must support resolve according to § 26.1.1 Plain color formats.

A GPUTextureView view is a renderable texture view if the all of the requirements in the following device timeline steps are met:
  1. Let descriptor be view.[[descriptor]].

  2. descriptor.usage must contain RENDER_ATTACHMENT.

  3. descriptor.dimension must be "2d" or "2d-array" or "3d".

  4. descriptor.mipLevelCount must be 1.

  5. descriptor.arrayLayerCount must be 1.

  6. descriptor.aspect must refer to all aspects of view.[[texture]].

Calculating color attachment bytes per sample(formats)

Arguments:

Returns: GPUSize32

  1. Let total be 0.

  2. For each non-null format in formats

    1. Assert: format is a color renderable format.

    2. Let renderTargetPixelByteCost be the render target pixel byte cost of format.

    3. Let renderTargetComponentAlignment be the render target component alignment of format.

    4. Round total up to the smallest multiple of renderTargetComponentAlignment greater than or equal to total.

    5. Add renderTargetPixelByteCost to total.

  3. Return total.

17.1.1.2. Depth/Stencil Attachments
dictionary GPURenderPassDepthStencilAttachment {
    required GPUTextureView view;

    float depthClearValue;
    GPULoadOp depthLoadOp;
    GPUStoreOp depthStoreOp;
    boolean depthReadOnly = false;

    GPUStencilValue stencilClearValue = 0;
    GPULoadOp stencilLoadOp;
    GPUStoreOp stencilStoreOp;
    boolean stencilReadOnly = false;
};
view, of type GPUTextureView

A GPUTextureView describing the texture subresource that will be output to and read from for this depth/stencil attachment.

depthClearValue, of type float

Indicates the value to clear view's depth component to prior to executing the render pass. Ignored if depthLoadOp is not "clear". Must be between 0.0 and 1.0, inclusive.

depthLoadOp, of type GPULoadOp

Indicates the load operation to perform on view's depth component prior to executing the render pass.

Note: It is recommended to prefer clearing; see "clear" for details.

depthStoreOp, of type GPUStoreOp

The store operation to perform on view's depth component after executing the render pass.

depthReadOnly, of type boolean, defaulting to false

Indicates that the depth component of view is read only.

stencilClearValue, of type GPUStencilValue, defaulting to 0

Indicates the value to clear view's stencil component to prior to executing the render pass. Ignored if stencilLoadOp is not "clear".

The value will be converted to the type of the stencil aspect of view by taking the same number of LSBs as the number of bits in the stencil aspect of one texel of view.

stencilLoadOp, of type GPULoadOp

Indicates the load operation to perform on view's stencil component prior to executing the render pass.

Note: It is recommended to prefer clearing; see "clear" for details.

stencilStoreOp, of type GPUStoreOp

The store operation to perform on view's stencil component after executing the render pass.

stencilReadOnly, of type boolean, defaulting to false

Indicates that the stencil component of view is read only.

GPURenderPassDepthStencilAttachment Valid Usage

Given a GPURenderPassDepthStencilAttachment this, the following validation rules apply:

17.1.1.3. Load & Store Operations
enum GPULoadOp {
    "load",
    "clear",
};
"load"

Loads the existing value for this attachment into the render pass.

"clear"

Loads a clear value for this attachment into the render pass.

Note: On some GPU hardware (primarily mobile), "clear" is significantly cheaper because it avoids loading data from main memory into tile-local memory. On other GPU hardware, there isn’t a significant difference. As a result, it is recommended to use "clear" rather than "load" in cases where the initial value doesn’t matter (e.g. the render target will be cleared using a skybox).

enum GPUStoreOp {
    "store",
    "discard",
};
"store"

Stores the resulting value of the render pass for this attachment.

"discard"

Discards the resulting value of the render pass for this attachment.

Note: Discarded attachments behave as if they are cleared to zero, but implementations are not required to perform a clear at the end of the render pass. Implementations which do not explicitly clear discarded attachments at the end of a pass must lazily clear them prior to the reading the attachment contents, which occurs via sampling, copies, attaching to a later render pass with "load", displaying or reading back the canvas (get a copy of the image contents of a context), etc.

17.1.1.4. Render Pass Layout

GPURenderPassLayout declares the layout of the render targets of a GPURenderBundle. It is also used internally to describe GPURenderPassEncoder layouts and GPURenderPipeline layouts. It determines compatibility between render passes, render bundles, and render pipelines.

dictionary GPURenderPassLayout
         : GPUObjectDescriptorBase {
    required sequence<GPUTextureFormat?> colorFormats;
    GPUTextureFormat depthStencilFormat;
    GPUSize32 sampleCount = 1;
};
colorFormats, of type sequence<GPUTextureFormat?>

A list of the GPUTextureFormats of the color attachments for this pass or bundle.

depthStencilFormat, of type GPUTextureFormat

The GPUTextureFormat of the depth/stencil attachment for this pass or bundle.

sampleCount, of type GPUSize32, defaulting to 1

Number of samples per pixel in the attachments for this pass or bundle.

Two GPURenderPassLayout values are equal if:
derive render targets layout from pass

Arguments:

Returns: GPURenderPassLayout

Device timeline steps:

  1. Let layout be a new GPURenderPassLayout object.

  2. For each colorAttachment in descriptor.colorAttachments:

    1. If colorAttachment is not null:

      1. Set layout.sampleCount to colorAttachment.view.[[texture]].sampleCount.

      2. Append colorAttachment.view.[[descriptor]].format to layout.colorFormats.

    2. Otherwise:

      1. Append null to layout.colorFormats.

  3. Let depthStencilAttachment be descriptor.depthStencilAttachment.

  4. If depthStencilAttachment is not null:

    1. Let view be depthStencilAttachment.view.

    2. Set layout.sampleCount to view.[[texture]].sampleCount.

    3. Set layout.depthStencilFormat to view.[[descriptor]].format.

  5. Return layout.

derive render targets layout from pipeline

Arguments:

Returns: GPURenderPassLayout

Device timeline steps:

  1. Let layout be a new GPURenderPassLayout object.

  2. Set layout.sampleCount to descriptor.multisample.count.

  3. If descriptor.depthStencil is provided:

    1. Set layout.depthStencilFormat to descriptor.depthStencil.format.

  4. If descriptor.fragment is provided:

    1. For each colorTarget in descriptor.fragment.targets:

      1. Append colorTarget.format to layout.colorFormats if colorTarget is not null, or append null otherwise.

  5. Return layout.

17.1.2. Finalization

The render pass encoder can be ended by calling end() once the user has finished recording commands for the pass. Once end() has been called the render pass encoder can no longer be used.

end()

Completes recording of the render pass commands sequence.

Called on: GPURenderPassEncoder this.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Let parentEncoder be this.[[command_encoder]].

  2. If any of the following requirements are unmet, generate a validation error and return.

  3. Set this.[[state]] to "ended".

  4. Set parentEncoder.[[state]] to "open".

  5. If any of the following requirements are unmet, invalidate parentEncoder and return.

  6. Extend parentEncoder.[[commands]] with this.[[commands]].

  7. If this.[[endTimestampWrite]] is not null:

    1. Extend parentEncoder.[[commands]] with this.[[endTimestampWrite]].

  8. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. For each non-null colorAttachment in renderState.[[colorAttachments]]:

    1. Let colorView be colorAttachment.view.

    2. If colorView.[[descriptor]].dimension is:

      "3d"

      Let colorSubregion be colorAttachment.depthSlice of colorView.

      Otherwise

      Let colorSubregion be colorView.

    3. If colorAttachment.resolveTarget is not null:

      1. Resolve the multiple samples of every texel of colorSubregion to a single sample and copy to colorAttachment.resolveTarget.

    4. If colorAttachment.loadOp is:

      "store"

      Ensure the contents of the framebuffer memory associated with colorSubregion are stored in colorSubregion.

      "discard"

      Set every texel of colorSubregion to zero.

  2. Let depthStencilAttachment be renderState.[[depthStencilAttachment]].

  3. If depthStencilAttachment is not null:

    1. If depthStencilAttachment.depthLoadOp is:

      Not provided

      Assert that depthStencilAttachment.depthReadOnly is true and leave the depth subresource of depthStencilView unchanged.

      "store"

      Ensure the contents of the framebuffer memory associated with the depth subresource of depthStencilView are stored in depthStencilView.

      "discard"

      Set every texel in the depth subresource of depthStencilView to zero.

    2. If depthStencilAttachment.stencilLoadOp is:

      Not provided

      Assert that depthStencilAttachment.stencilReadOnly is true and leave the stencil subresource of depthStencilView unchanged.

      "store"

      Ensure the contents of the framebuffer memory associated with the stencil subresource of depthStencilView are stored in depthStencilView.

      "discard"

      Set every texel in the stencil subresource depthStencilView to zero.

  4. Let renderState be null.

Note: Discarded attachments behave as if they are cleared to zero, but implementations are not required to perform a clear at the end of the render pass. See the note on "discard" for additional details.

Note: Read-only depth-stencil attachments can be thought of as implicitly using the "store" operation, but since their content is unchanged during the render pass implementations don’t need to update the attachment. Validation that requires the store op to not be provided for read-only attachments is done in GPURenderPassDepthStencilAttachment Valid Usage.

17.2. GPURenderCommandsMixin

GPURenderCommandsMixin defines rendering commands common to GPURenderPassEncoder and GPURenderBundleEncoder.

interface mixin GPURenderCommandsMixin {
    undefined setPipeline(GPURenderPipeline pipeline);

    undefined setIndexBuffer(GPUBuffer buffer, GPUIndexFormat indexFormat, optional GPUSize64 offset = 0, optional GPUSize64 size);
    undefined setVertexBuffer(GPUIndex32 slot, GPUBuffer? buffer, optional GPUSize64 offset = 0, optional GPUSize64 size);

    undefined draw(GPUSize32 vertexCount, optional GPUSize32 instanceCount = 1,
        optional GPUSize32 firstVertex = 0, optional GPUSize32 firstInstance = 0);
    undefined drawIndexed(GPUSize32 indexCount, optional GPUSize32 instanceCount = 1,
        optional GPUSize32 firstIndex = 0,
        optional GPUSignedOffset32 baseVertex = 0,
        optional GPUSize32 firstInstance = 0);

    undefined drawIndirect(GPUBuffer indirectBuffer, GPUSize64 indirectOffset);
    undefined drawIndexedIndirect(GPUBuffer indirectBuffer, GPUSize64 indirectOffset);
};

GPURenderCommandsMixin assumes the presence of GPUObjectBase, GPUCommandsMixin, and GPUBindingCommandsMixin members on the same object. It must only be included by interfaces which also include those mixins.

GPURenderCommandsMixin has the following device timeline properties:

[[layout]], of type GPURenderPassLayout, readonly

The layout of the render pass.

[[depthReadOnly]], of type boolean, readonly

If true, indicates that the depth component is not modified.

[[stencilReadOnly]], of type boolean, readonly

If true, indicates that the stencil component is not modified.

[[usage scope]], of type usage scope, initially empty

The usage scope for this render pass or bundle.

[[pipeline]], of type GPURenderPipeline, initially null

The current GPURenderPipeline.

[[index_buffer]], of type GPUBuffer, initially null

The current buffer to read index data from.

[[index_format]], of type GPUIndexFormat

The format of the index data in [[index_buffer]].

[[index_buffer_offset]], of type GPUSize64

The offset in bytes of the section of [[index_buffer]] currently set.

[[index_buffer_size]], of type GPUSize64

The size in bytes of the section of [[index_buffer]] currently set, initially 0.

[[vertex_buffers]], of type ordered map<slot, GPUBuffer>, initially empty

The current GPUBuffers to read vertex data from for each slot.

[[vertex_buffer_sizes]], of type ordered map<slot, GPUSize64>, initially empty

The size in bytes of the section of GPUBuffer currently set for each slot.

[[drawCount]], of type GPUSize64

The number of draw commands recorded in this encoder.

To Enqueue a render command on GPURenderCommandsMixin encoder which issues the steps of a GPU Command command with RenderState renderState, run the following device timeline steps:
  1. Append command to encoder.[[commands]].

  2. When command is executed as part of a GPUCommandBuffer commandBuffer:

    1. Issue the steps of command with commandBuffer.[[renderState]] as renderState.

17.2.1. Drawing

setPipeline(pipeline)

Sets the current GPURenderPipeline.

Called on: GPURenderCommandsMixin this.

Arguments:

Arguments for the GPURenderCommandsMixin.setPipeline(pipeline) method.
Parameter Type Nullable Optional Description
pipeline GPURenderPipeline The render pipeline to use for subsequent drawing commands.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Let pipelineTargetsLayout be derive render targets layout from pipeline(pipeline.[[descriptor]]).

  3. If any of the following conditions are unsatisfied, invalidate this and return.

  4. Set this.[[pipeline]] to be pipeline.

setIndexBuffer(buffer, indexFormat, offset, size)

Sets the current index buffer.

Called on: GPURenderCommandsMixin this.

Arguments:

Arguments for the GPURenderCommandsMixin.setIndexBuffer(buffer, indexFormat, offset, size) method.
Parameter Type Nullable Optional Description
buffer GPUBuffer Buffer containing index data to use for subsequent drawing commands.
indexFormat GPUIndexFormat Format of the index data contained in buffer.
offset GPUSize64 Offset in bytes into buffer where the index data begins. Defaults to 0.
size GPUSize64 Size in bytes of the index data in buffer. Defaults to the size of the buffer minus the offset.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If size is missing, set size to max(0, buffer.size - offset).

  3. If any of the following conditions are unsatisfied, invalidate this and return.

  4. Add buffer to [[usage scope]] with usage input.

  5. Set this.[[index_buffer]] to be buffer.

  6. Set this.[[index_format]] to be indexFormat.

  7. Set this.[[index_buffer_offset]] to be offset.

  8. Set this.[[index_buffer_size]] to be size.

setVertexBuffer(slot, buffer, offset, size)

Sets the current vertex buffer for the given slot.

Called on: GPURenderCommandsMixin this.

Arguments:

Arguments for the GPURenderCommandsMixin.setVertexBuffer(slot, buffer, offset, size) method.
Parameter Type Nullable Optional Description
slot GPUIndex32 The vertex buffer slot to set the vertex buffer for.
buffer GPUBuffer? Buffer containing vertex data to use for subsequent drawing commands.
offset GPUSize64 Offset in bytes into buffer where the vertex data begins. Defaults to 0.
size GPUSize64 Size in bytes of the vertex data in buffer. Defaults to the size of the buffer minus the offset.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Let bufferSize be 0 if buffer is null, or buffer.size if not.

  3. If size is missing, set size to max(0, bufferSize - offset).

  4. If any of the following requirements are unmet, invalidate this and return.

  5. If buffer is null:

    1. Remove this.[[vertex_buffers]][slot].

    2. Remove this.[[vertex_buffer_sizes]][slot].

    Otherwise:

    1. If any of the following requirements are unmet, invalidate this and return.

    2. Add buffer to [[usage scope]] with usage input.

    3. Set this.[[vertex_buffers]][slot] to be buffer.

    4. Set this.[[vertex_buffer_sizes]][slot] to be size.

draw(vertexCount, instanceCount, firstVertex, firstInstance)

Draws primitives. See § 23.2 Rendering for the detailed specification.

Called on: GPURenderCommandsMixin this.

Arguments:

Arguments for the GPURenderCommandsMixin.draw(vertexCount, instanceCount, firstVertex, firstInstance) method.
Parameter Type Nullable Optional Description
vertexCount GPUSize32 The number of vertices to draw.
instanceCount GPUSize32 The number of instances to draw.
firstVertex GPUSize32 Offset into the vertex buffers, in vertices, to begin drawing from.
firstInstance GPUSize32 First instance to draw.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. All of the requirements in the following steps must be met. If any are unmet, invalidate this and return.

    1. It must be valid to draw with this.

    2. Let buffers be this.[[pipeline]].[[descriptor]].vertex.buffers.

    3. For each GPUIndex32 slot from 0 to buffers.size (non-inclusive):

      1. If buffers[slot] is null, continue.

      2. Let bufferSize be this.[[vertex_buffer_sizes]][slot].

      3. Let stride be buffers[slot].arrayStride.

      4. Let attributes be buffers[slot].attributes

      5. Let lastStride be the maximum value of (attribute.offset + byteSize(attribute.format)) over each attribute in attributes, or 0 if attributes is empty.

      6. Let strideCount be computed based on buffers[slot].stepMode:

        "vertex"

        firstVertex + vertexCount

        "instance"

        firstInstance + instanceCount

      7. If strideCount0:

        1. (strideCount1) × stride + lastStride must be ≤ bufferSize.

  3. Increment this.[[drawCount]] by 1.

  4. Let bindingState be a snapshot of this’s current state.

  5. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Draw instanceCount instances, starting with instance firstInstance, of primitives consisting of vertexCount vertices, starting with vertex firstVertex, with the states from bindingState and renderState.

drawIndexed(indexCount, instanceCount, firstIndex, baseVertex, firstInstance)

Draws indexed primitives. See § 23.2 Rendering for the detailed specification.

Called on: GPURenderCommandsMixin this.

Arguments:

Arguments for the GPURenderCommandsMixin.drawIndexed(indexCount, instanceCount, firstIndex, baseVertex, firstInstance) method.
Parameter Type Nullable Optional Description
indexCount GPUSize32 The number of indices to draw.
instanceCount GPUSize32 The number of instances to draw.
firstIndex GPUSize32 Offset into the index buffer, in indices, begin drawing from.
baseVertex GPUSignedOffset32 Added to each index value before indexing into the vertex buffers.
firstInstance GPUSize32 First instance to draw.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Increment this.[[drawCount]] by 1.

  4. Let bindingState be a snapshot of this’s current state.

  5. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Draw instanceCount instances, starting with instance firstInstance, of primitives consisting of indexCount indexed vertices, starting with index firstIndex from vertex baseVertex, with the states from bindingState and renderState.

Note: WebGPU applications should never use index data with indices out of bounds of any bound vertex buffer that has GPUVertexStepMode "vertex". WebGPU implementations have different ways of handling this, and therefore a range of behaviors is allowed. Either the whole draw call is discarded, or the access to those attributes out of bounds is described by WGSL’s invalid memory reference.

drawIndirect(indirectBuffer, indirectOffset)

Draws primitives using parameters read from a GPUBuffer. See § 23.2 Rendering for the detailed specification.

The indirect draw parameters encoded in the buffer must be a tightly packed block of four 32-bit unsigned integer values (16 bytes total), given in the same order as the arguments for draw(). For example:

let drawIndirectParameters = new Uint32Array(4);
drawIndirectParameters[0] = vertexCount;
drawIndirectParameters[1] = instanceCount;
drawIndirectParameters[2] = firstVertex;
drawIndirectParameters[3] = firstInstance;

The value corresponding to firstInstance must be 0, unless the "indirect-first-instance" feature is enabled. If the "indirect-first-instance" feature is not enabled and firstInstance is not zero the drawIndirect() call will be treated as a no-op.

Called on: GPURenderCommandsMixin this.

Arguments:

Arguments for the GPURenderCommandsMixin.drawIndirect(indirectBuffer, indirectOffset) method.
Parameter Type Nullable Optional Description
indirectBuffer GPUBuffer Buffer containing the indirect draw parameters.
indirectOffset GPUSize64 Offset in bytes into indirectBuffer where the drawing data begins.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Add indirectBuffer to [[usage scope]] with usage input.

  4. Increment this.[[drawCount]] by 1.

  5. Let bindingState be a snapshot of this’s current state.

  6. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Let vertexCount be an unsigned 32-bit integer read from indirectBuffer at indirectOffset bytes.

  2. Let instanceCount be an unsigned 32-bit integer read from indirectBuffer at (indirectOffset + 4) bytes.

  3. Let firstVertex be an unsigned 32-bit integer read from indirectBuffer at (indirectOffset + 8) bytes.

  4. Let firstInstance be an unsigned 32-bit integer read from indirectBuffer at (indirectOffset + 12) bytes.

  5. Draw instanceCount instances, starting with instance firstInstance, of primitives consisting of vertexCount vertices, starting with vertex firstVertex, with the states from bindingState and renderState.

drawIndexedIndirect(indirectBuffer, indirectOffset)

Draws indexed primitives using parameters read from a GPUBuffer. See § 23.2 Rendering for the detailed specification.

The indirect drawIndexed parameters encoded in the buffer must be a tightly packed block of five 32-bit values (20 bytes total), given in the same order as the arguments for drawIndexed(). The value corresponding to baseVertex is a signed 32-bit integer, and all others are unsigned 32-bit integers. For example:

let drawIndexedIndirectParameters = new Uint32Array(5);
let drawIndexedIndirectParametersSigned = new Int32Array(drawIndexedIndirectParameters.buffer);
drawIndexedIndirectParameters[0] = indexCount;
drawIndexedIndirectParameters[1] = instanceCount;
drawIndexedIndirectParameters[2] = firstIndex;
// baseVertex is a signed value.
drawIndexedIndirectParametersSigned[3] = baseVertex;
drawIndexedIndirectParameters[4] = firstInstance;

The value corresponding to firstInstance must be 0, unless the "indirect-first-instance" feature is enabled. If the "indirect-first-instance" feature is not enabled and firstInstance is not zero the drawIndexedIndirect() call will be treated as a no-op.

Called on: GPURenderCommandsMixin this.

Arguments:

Arguments for the GPURenderCommandsMixin.drawIndexedIndirect(indirectBuffer, indirectOffset) method.
Parameter Type Nullable Optional Description
indirectBuffer GPUBuffer Buffer containing the indirect drawIndexed parameters.
indirectOffset GPUSize64 Offset in bytes into indirectBuffer where the drawing data begins.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Add indirectBuffer to [[usage scope]] with usage input.

  4. Increment this.[[drawCount]] by 1.

  5. Let bindingState be a snapshot of this’s current state.

  6. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Let indexCount be an unsigned 32-bit integer read from indirectBuffer at indirectOffset bytes.

  2. Let instanceCount be an unsigned 32-bit integer read from indirectBuffer at (indirectOffset + 4) bytes.

  3. Let firstIndex be an unsigned 32-bit integer read from indirectBuffer at (indirectOffset + 8) bytes.

  4. Let baseVertex be a signed 32-bit integer read from indirectBuffer at (indirectOffset + 12) bytes.

  5. Let firstInstance be an unsigned 32-bit integer read from indirectBuffer at (indirectOffset + 16) bytes.

  6. Draw instanceCount instances, starting with instance firstInstance, of primitives consisting of indexCount indexed vertices, starting with index firstIndex from vertex baseVertex, with the states from bindingState and renderState.

To determine if it’s valid to draw with GPURenderCommandsMixin encoder, run the following device timeline steps:
  1. If any of the following conditions are unsatisfied, return false:

  2. Otherwise return true.

To determine if it’s valid to draw indexed with GPURenderCommandsMixin encoder, run the following device timeline steps:
  1. If any of the following conditions are unsatisfied, return false:

  2. Otherwise return true.

17.2.2. Rasterization state

The GPURenderPassEncoder has several methods which affect how draw commands are rasterized to attachments used by this encoder.

setViewport(x, y, width, height, minDepth, maxDepth)

Sets the viewport used during the rasterization stage to linearly map from normalized device coordinates to viewport coordinates.

Called on: GPURenderPassEncoder this.

Arguments:

Arguments for the GPURenderPassEncoder.setViewport(x, y, width, height, minDepth, maxDepth) method.
Parameter Type Nullable Optional Description
x float Minimum X value of the viewport in pixels.
y float Minimum Y value of the viewport in pixels.
width float Width of the viewport in pixels.
height float Height of the viewport in pixels.
minDepth float Minimum depth value of the viewport.
maxDepth float Maximum depth value of the viewport.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

    • x0

    • y0

    • width0

    • height0

    • x + widththis.[[attachment_size]].width

    • y + heightthis.[[attachment_size]].height

    • 0.0 ≤ minDepth ≤ 1.0

    • 0.0 ≤ maxDepth ≤ 1.0

    • minDepthmaxDepth

  3. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Round x, y, width, and height to some uniform precision, no less precise than integer rounding.

  2. Set renderState.[[viewport]] to the extents x, y, width, height, minDepth, and maxDepth.

setScissorRect(x, y, width, height)

Sets the scissor rectangle used during the rasterization stage. After transformation into viewport coordinates any fragments which fall outside the scissor rectangle will be discarded.

Called on: GPURenderPassEncoder this.

Arguments:

Arguments for the GPURenderPassEncoder.setScissorRect(x, y, width, height) method.
Parameter Type Nullable Optional Description
x GPUIntegerCoordinate Minimum X value of the scissor rectangle in pixels.
y GPUIntegerCoordinate Minimum Y value of the scissor rectangle in pixels.
width GPUIntegerCoordinate Width of the scissor rectangle in pixels.
height GPUIntegerCoordinate Height of the scissor rectangle in pixels.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Set renderState.[[scissorRect]] to the extents x, y, width, and height.

setBlendConstant(color)

Sets the constant blend color and alpha values used with "constant" and "one-minus-constant" GPUBlendFactors.

Called on: GPURenderPassEncoder this.

Arguments:

Arguments for the GPURenderPassEncoder.setBlendConstant(color) method.
Parameter Type Nullable Optional Description
color GPUColor The color to use when blending.

Returns: undefined

Content timeline steps:

  1. ? validate GPUColor shape(color).

  2. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Set renderState.[[blendConstant]] to color.

setStencilReference(reference)

Sets the [[stencilReference]] value used during stencil tests with the "replace" GPUStencilOperation.

Called on: GPURenderPassEncoder this.

Arguments:

Arguments for the GPURenderPassEncoder.setStencilReference(reference) method.
Parameter Type Nullable Optional Description
reference GPUStencilValue The new stencil reference value.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Set renderState.[[stencilReference]] to reference.

17.2.3. Queries

beginOcclusionQuery(queryIndex)
Called on: GPURenderPassEncoder this.

Arguments:

Arguments for the GPURenderPassEncoder.beginOcclusionQuery(queryIndex) method.
Parameter Type Nullable Optional Description
queryIndex GPUSize32 The index of the query in the query set.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Set this.[[occlusion_query_active]] to true.

  4. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Set renderState.[[occlusionQueryIndex]] to queryIndex.

endOcclusionQuery()
Called on: GPURenderPassEncoder this.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. Set this.[[occlusion_query_active]] to false.

  4. Enqueue a render command on this which issues the subsequent steps on the Queue timeline with renderState when executed.

Queue timeline steps:
  1. Let passingFragments be non-zero if any fragment samples passed all per-fragment tests since the corresponding beginOcclusionQuery() command was executed, and zero otherwise.

    Note: If no draw calls occurred, passingFragments is zero.

  2. Write passingFragments into this.[[occlusion_query_set]] at index renderState.[[occlusionQueryIndex]].

17.2.4. Bundles

executeBundles(bundles)

Executes the commands previously recorded into the given GPURenderBundles as part of this render pass.

When a GPURenderBundle is executed, it does not inherit the render pass’s pipeline, bind groups, or vertex and index buffers. After a GPURenderBundle has executed, the render pass’s pipeline, bind group, and vertex/index buffer state is cleared (to the initial, empty values).

Note: The state is cleared, not restored to the previous state. This occurs even if zero GPURenderBundles are executed.

Called on: GPURenderPassEncoder this.

Arguments:

Arguments for the GPURenderPassEncoder.executeBundles(bundles) method.
Parameter Type Nullable Optional Description
bundles sequence<GPURenderBundle> List of render bundles to execute.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.[[device]].

Device timeline steps:
  1. Validate the encoder state of this. If it returns false, return.

  2. If any of the following conditions are unsatisfied, invalidate this and return.

  3. For each bundle in bundles:

    1. Increment this.[[drawCount]] by bundle.[[drawCount]].

    2. Merge bundle.[[usage scope]] into this.[[usage scope]].

    3. Enqueue a render command on this which issues the following steps on the Queue timeline with renderState when executed:

      Queue timeline steps:
      1. Execute each command in bundle.[[command_list]] with renderState.

        Note: renderState cannot be changed by executing render bundles. Binding state was already captured at bundle encoding time, and so isn’t used when executing bundles.

  4. Reset the render pass binding state of this.

To Reset the render pass binding state of GPURenderPassEncoder encoder run the following device timeline steps:
  1. Clear encoder.[[bind_groups]].

  2. Set encoder.[[pipeline]] to null.

  3. Set encoder.[[index_buffer]] to null.

  4. Clear encoder.[[vertex_buffers]].

18. Bundles

A bundle is a partial, limited pass that is encoded once and can then be executed multiple times as part of future pass encoders without expiring after use like typical command buffers. This can reduce the overhead of encoding and submission of commands which are issued repeatedly without changing.

18.1. GPURenderBundle

[Exposed=(Window, Worker), SecureContext]
interface GPURenderBundle {
};
GPURenderBundle includes GPUObjectBase;
[[command_list]], of type list<GPU command>

A list of GPU commands to be submitted to the GPURenderPassEncoder when the GPURenderBundle is executed.

[[usage scope]], of type usage scope, initially empty

The usage scope for this render bundle, stored for later merging into the GPURenderPassEncoder's [[usage scope]] in executeBundles().

[[layout]], of type GPURenderPassLayout

The layout of the render bundle.

[[depthReadOnly]], of type boolean

If true, indicates that the depth component is not modified by executing this render bundle.

[[stencilReadOnly]], of type boolean

If true, indicates that the stencil component is not modified by executing this render bundle.

[[drawCount]], of type GPUSize64

The number of draw commands in this GPURenderBundle.

18.1.1. Render Bundle Creation

dictionary GPURenderBundleDescriptor
         : GPUObjectDescriptorBase {
};
[Exposed=(Window, Worker), SecureContext]
interface GPURenderBundleEncoder {
    GPURenderBundle finish(optional GPURenderBundleDescriptor descriptor = {});
};
GPURenderBundleEncoder includes GPUObjectBase;
GPURenderBundleEncoder includes GPUCommandsMixin;
GPURenderBundleEncoder includes GPUDebugCommandsMixin;
GPURenderBundleEncoder includes GPUBindingCommandsMixin;
GPURenderBundleEncoder includes GPURenderCommandsMixin;
createRenderBundleEncoder(descriptor)

Creates a GPURenderBundleEncoder.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createRenderBundleEncoder(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPURenderBundleEncoderDescriptor Description of the GPURenderBundleEncoder to create.

Returns: GPURenderBundleEncoder

Content timeline steps:

  1. ? Validate texture format required features of each non-null element of descriptor.colorFormats with this.[[device]].

  2. If descriptor.depthStencilFormat is provided:

    1. ? Validate texture format required features of descriptor.depthStencilFormat with this.[[device]].

  3. Let e be ! create a new WebGPU object(this, GPURenderBundleEncoder, descriptor).

  4. Issue the initialization steps on the Device timeline of this.

  5. Return e.

Device timeline initialization steps:
  1. If any of the following conditions are unsatisfied generate a validation error, invalidate e and return.

  2. Set e.[[layout]] to a copy of descriptor’s included GPURenderPassLayout interface.

  3. Set e.[[depthReadOnly]] to descriptor.depthReadOnly.

  4. Set e.[[stencilReadOnly]] to descriptor.stencilReadOnly.

  5. Set e.[[state]] to "open".

  6. Set e.[[drawCount]] to 0.

18.1.2. Encoding

dictionary GPURenderBundleEncoderDescriptor
         : GPURenderPassLayout {
    boolean depthReadOnly = false;
    boolean stencilReadOnly = false;
};
depthReadOnly, of type boolean, defaulting to false

If true, indicates that the render bundle does not modify the depth component of the GPURenderPassDepthStencilAttachment of any render pass the render bundle is executed in.

See read-only depth-stencil.

stencilReadOnly, of type boolean, defaulting to false

If true, indicates that the render bundle does not modify the stencil component of the GPURenderPassDepthStencilAttachment of any render pass the render bundle is executed in.

See read-only depth-stencil.

18.1.3. Finalization

finish(descriptor)

Completes recording of the render bundle commands sequence.

Called on: GPURenderBundleEncoder this.

Arguments:

Arguments for the GPURenderBundleEncoder.finish(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPURenderBundleDescriptor

Returns: GPURenderBundle

Content timeline steps:

  1. Let renderBundle be a new GPURenderBundle.

  2. Issue the finish steps on the Device timeline of this.[[device]].

  3. Return renderBundle.

Device timeline finish steps:
  1. Let validationSucceeded be true if all of the following requirements are met, and false otherwise.

  2. Set this.[[state]] to "ended".

  3. If validationSucceeded is false, then:

    1. Generate a validation error.

    2. Return an invalidated GPURenderBundle.

  4. Set renderBundle.[[command_list]] to this.[[commands]].

  5. Set renderBundle.[[usage scope]] to this.[[usage scope]].

  6. Set renderBundle.[[drawCount]] to this.[[drawCount]].

19. Queues

19.1. GPUQueueDescriptor

GPUQueueDescriptor describes a queue request.

dictionary GPUQueueDescriptor
         : GPUObjectDescriptorBase {
};

19.2. GPUQueue

[Exposed=(Window, Worker), SecureContext]
interface GPUQueue {
    undefined submit(sequence<GPUCommandBuffer> commandBuffers);

    Promise<undefined> onSubmittedWorkDone();

    undefined writeBuffer(
        GPUBuffer buffer,
        GPUSize64 bufferOffset,
        AllowSharedBufferSource data,
        optional GPUSize64 dataOffset = 0,
        optional GPUSize64 size);

    undefined writeTexture(
        GPUTexelCopyTextureInfo destination,
        AllowSharedBufferSource data,
        GPUTexelCopyBufferLayout dataLayout,
        GPUExtent3D size);

    undefined copyExternalImageToTexture(
        GPUCopyExternalImageSourceInfo source,
        GPUCopyExternalImageDestInfo destination,
        GPUExtent3D copySize);
};
GPUQueue includes GPUObjectBase;

GPUQueue has the following methods:

writeBuffer(buffer, bufferOffset, data, dataOffset, size)

Issues a write operation of the provided data into a GPUBuffer.

Called on: GPUQueue this.

Arguments:

Arguments for the GPUQueue.writeBuffer(buffer, bufferOffset, data, dataOffset, size) method.
Parameter Type Nullable Optional Description
buffer GPUBuffer The buffer to write to.
bufferOffset GPUSize64 Offset in bytes into buffer to begin writing at.
data AllowSharedBufferSource Data to write into buffer.
dataOffset GPUSize64 Offset in into data to begin writing from. Given in elements if data is a TypedArray and bytes otherwise.
size GPUSize64 Size of content to write from data to buffer. Given in elements if data is a TypedArray and bytes otherwise.

Returns: undefined

Content timeline steps:

  1. If data is an ArrayBuffer or DataView, let the element type be "byte". Otherwise, data is a TypedArray; let the element type be the type of the TypedArray.

  2. Let dataSize be the size of data, in elements.

  3. If size is missing, let contentsSize be dataSizedataOffset. Otherwise, let contentsSize be size.

  4. If any of the following conditions are unsatisfied, throw an OperationError and return.

    • contentsSize ≥ 0.

    • dataOffset + contentsSizedataSize.

    • contentsSize, converted to bytes, is a multiple of 4 bytes.

  5. Let dataContents be a copy of the bytes held by the buffer source data.

  6. Let contents be the contentsSize elements of dataContents starting at an offset of dataOffset elements.

  7. Issue the subsequent steps on the Device timeline of this.

Device timeline steps:
  1. If any of the following conditions are unsatisfied, generate a validation error and return.

  2. Issue the subsequent steps on the Queue timeline of this.

Queue timeline steps:
  1. Write contents into buffer starting at bufferOffset.

writeTexture(destination, data, dataLayout, size)

Issues a write operation of the provided data into a GPUTexture.

Called on: GPUQueue this.

Arguments:

Arguments for the GPUQueue.writeTexture(destination, data, dataLayout, size) method.
Parameter Type Nullable Optional Description
destination GPUTexelCopyTextureInfo The texture subresource and origin to write to.
data AllowSharedBufferSource Data to write into destination.
dataLayout GPUTexelCopyBufferLayout Layout of the content in data.
size GPUExtent3D Extents of the content to write from data to destination.

Returns: undefined

Content timeline steps:

  1. ? validate GPUOrigin3D shape(destination.origin).

  2. ? validate GPUExtent3D shape(size).

  3. Let dataBytes be a copy of the bytes held by the buffer source data.

    Note: This is described as copying all of data to the device timeline, but in practice data could be much larger than necessary. Implementations should optimize by copying only the necessary bytes.

  4. Issue the subsequent steps on the Device timeline of this.

Device timeline steps:
  1. Let aligned be false.

  2. Let dataLength be dataBytes.length.

  3. If any of the following conditions are unsatisfied, generate a validation error and return.

    Note: unlike GPUCommandEncoder.copyBufferToTexture(), there is no alignment requirement on either dataLayout.bytesPerRow or dataLayout.offset.

  4. Issue the subsequent steps on the Queue timeline of this.

Queue timeline steps:
  1. Let blockWidth be the texel block width of destination.texture.

  2. Let blockHeight be the texel block height of destination.texture.

  3. Let dstOrigin be destination.origin;

  4. Let dstBlockOriginX be (dstOrigin.x ÷ blockWidth).

  5. Let dstBlockOriginY be (dstOrigin.y ÷ blockHeight).

  6. Let blockColumns be (copySize.width ÷ blockWidth).

  7. Let blockRows be (copySize.height ÷ blockHeight).

  8. Assert that dstBlockOriginX, dstBlockOriginY, blockColumns, and blockRows are integers.

  9. For each z in the range [0, copySize.depthOrArrayLayers − 1]:

    1. Let dstSubregion be texture copy sub-region (z + dstOrigin.z) of destination.

    2. For each y in the range [0, blockRows − 1]:

      1. For each x in the range [0, blockColumns − 1]:

        1. Let blockOffset be the texel block byte offset of dataLayout for (x, y, z) of destination.texture.

        2. Set texel block (dstBlockOriginX + x, dstBlockOriginY + y) of dstSubregion to be an equivalent texel representation to the texel block described by dataBytes at offset blockOffset.

copyExternalImageToTexture(source, destination, copySize)

Issues a copy operation of the contents of a platform image/canvas into the destination texture.

This operation performs color encoding into the destination encoding according to the parameters of GPUCopyExternalImageDestInfo.

Copying into a -srgb texture results in the same texture bytes, not the same decoded values, as copying into the corresponding non--srgb format. Thus, after a copy operation, sampling the destination texture has different results depending on whether its format is -srgb, all else unchanged.

NOTE:
When copying from a "webgl"/"webgl2" context canvas, the WebGL Drawing Buffer may be not exist during certain points in the frame presentation cycle (after the image has been moved to the compositor for display). To avoid this, either:
  • Issue copyExternalImageToTexture() in the same task with WebGL rendering operation, to ensure the copy occurs before the WebGL canvas is presented.

  • If not possible, set the preserveDrawingBuffer option in WebGLContextAttributes to true, so that the drawing buffer will still contain a copy of the frame contents after they’ve been presented. Note, this extra copy may have a performance cost.

Called on: GPUQueue this.

Arguments:

Arguments for the GPUQueue.copyExternalImageToTexture(source, destination, copySize) method.
Parameter Type Nullable Optional Description
source GPUCopyExternalImageSourceInfo source image and origin to copy to destination.
destination GPUCopyExternalImageDestInfo The texture subresource and origin to write to, and its encoding metadata.
copySize GPUExtent3D Extents of the content to write from source to destination.

Returns: undefined

Content timeline steps:

  1. ? validate GPUOrigin2D shape(source.origin).

  2. ? validate GPUOrigin3D shape(destination.origin).

  3. ? validate GPUExtent3D shape(copySize).

  4. Let sourceImage be source.source

  5. If sourceImage is not origin-clean, throw a SecurityError and return.

  6. If any of the following requirements are unmet, throw an OperationError and return.

    • source.origin.x + copySize.width must be ≤ the width of sourceImage.

    • source.origin.y + copySize.height must be ≤ the height of sourceImage.

    • copySize.depthOrArrayLayers must be ≤ 1.

  7. Let usability be ? check the usability of the image argument(source).

  8. Issue the subsequent steps on the Device timeline of this.

Device timeline steps:
  1. Let texture be destination.texture.

  2. If any of the following requirements are unmet, generate a validation error and return.

  3. If copySize.depthOrArrayLayers is > 0, issue the subsequent steps on the Queue timeline of this.

Queue timeline steps:
  1. Assert that the texel block width of destination.texture is 1, the texel block height of destination.texture is 1, and that copySize.depthOrArrayLayers is 1.

  2. Let srcOrigin be source.origin.

  3. Let dstOrigin be destination.origin.

  4. Let dstSubregion be texture copy sub-region (dstOrigin.z) of destination.

  5. For each y in the range [0, copySize.height − 1]:

    1. Let srcY be y if source.flipY is false and (copySize.height − 1 − y) otherwise.

    2. For each x in the range [0, copySize.width − 1]:

      1. Set texel block (dstOrigin.x + x, dstOrigin.y + y) of dstSubregion to be an equivalent texel representation of the pixel at (srcOrigin.x + x, srcOrigin.y + srcY) of source.source after applying any color encoding required by destination.colorSpace and destination.premultipliedAlpha.

submit(commandBuffers)

Schedules the execution of the command buffers by the GPU on this queue.

Submitted command buffers cannot be used again.

Called on: GPUQueue this.

Arguments:

Arguments for the GPUQueue.submit(commandBuffers) method.
Parameter Type Nullable Optional Description
commandBuffers sequence<GPUCommandBuffer>

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this:

Device timeline steps:
  1. If any of the following requirements are unmet, generate a validation error, invalidate each GPUCommandBuffer in commandBuffers and return.

  2. For each commandBuffer in commandBuffers:

    1. Invalidate commandBuffer.

  3. Issue the subsequent steps on the Queue timeline of this:

Queue timeline steps:
  1. For each commandBuffer in commandBuffers:

    1. Execute each command in commandBuffer.[[command_list]].

onSubmittedWorkDone()

Returns a Promise that resolves once this queue finishes processing all the work submitted up to this moment.

Resolution of this Promise implies the completion of mapAsync() calls made prior to that call, on GPUBuffers last used exclusively on that queue.

Called on: GPUQueue this.

Returns: Promise<undefined>

Content timeline steps:

  1. Let contentTimeline be the current Content timeline.

  2. Let promise be a new promise.

  3. Issue the synchronization steps on the Device timeline of this.

  4. Return promise.

Device timeline synchronization steps:
  1. Let event occur upon the completion of all currently-enqueued operations.

  2. Listen for timeline event event on this.[[device]], handled by the subsequent steps on contentTimeline.

Content timeline steps:
  1. Resolve promise.

20. Queries

20.1. GPUQuerySet

[Exposed=(Window, Worker), SecureContext]
interface GPUQuerySet {
    undefined destroy();

    readonly attribute GPUQueryType type;
    readonly attribute GPUSize32Out count;
};
GPUQuerySet includes GPUObjectBase;

GPUQuerySet has the following immutable properties:

type, of type GPUQueryType, readonly

The type of the queries managed by this GPUQuerySet.

count, of type GPUSize32Out, readonly

The number of queries managed by this GPUQuerySet.

GPUQuerySet has the following device timeline properties:

[[destroyed]], of type boolean, initially false

If the query set is destroyed, it can no longer be used in any operation, and its underlying memory can be freed.

20.1.1. QuerySet Creation

A GPUQuerySetDescriptor specifies the options to use in creating a GPUQuerySet.

dictionary GPUQuerySetDescriptor
         : GPUObjectDescriptorBase {
    required GPUQueryType type;
    required GPUSize32 count;
};
type, of type GPUQueryType

The type of queries managed by GPUQuerySet.

count, of type GPUSize32

The number of queries managed by GPUQuerySet.

createQuerySet(descriptor)

Creates a GPUQuerySet.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.createQuerySet(descriptor) method.
Parameter Type Nullable Optional Description
descriptor GPUQuerySetDescriptor Description of the GPUQuerySet to create.

Returns: GPUQuerySet

Content timeline steps:

  1. If descriptor.type is "timestamp", but "timestamp-query" is not enabled for this:

    1. Throw a TypeError.

  2. Let q be ! create a new WebGPU object(this, GPUQuerySet, descriptor).

  3. Set q.type to descriptor.type.

  4. Set q.count to descriptor.count.

  5. Issue the initialization steps on the Device timeline of this.

  6. Return q.

Device timeline initialization steps:
  1. If any of the following requirements are unmet, generate a validation error, invalidate q and return.

    • this must not be lost.

    • descriptor.count must be ≤ 4096.

  2. Create a device allocation for q where each entry in the query set is zero.

    If the allocation fails without side-effects, generate an out-of-memory error, invalidate q, and return.

Creating a GPUQuerySet which holds 32 occlusion query results.
const querySet = gpuDevice.createQuerySet({
    type: 'occlusion',
    count: 32
});

20.1.2. Query Set Destruction

An application that no longer requires a GPUQuerySet can choose to lose access to it before garbage collection by calling destroy().

GPUQuerySet has the following methods:

destroy()

Destroys the GPUQuerySet.

Called on: GPUQuerySet this.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the device timeline.

Device timeline steps:
  1. Set this.[[destroyed]] to true.

20.2. QueryType

enum GPUQueryType {
    "occlusion",
    "timestamp",
};

20.3. Occlusion Query

Occlusion query is only available on render passes, to query the number of fragment samples that pass all the per-fragment tests for a set of drawing commands, including scissor, sample mask, alpha to coverage, stencil, and depth tests. Any non-zero result value for the query indicates that at least one sample passed the tests and reached the output merging stage of the render pipeline, 0 indicates that no samples passed the tests.

When beginning a render pass, GPURenderPassDescriptor.occlusionQuerySet must be set to be able to use occlusion queries during the pass. An occlusion query is begun and ended by calling beginOcclusionQuery() and endOcclusionQuery() in pairs that cannot be nested, and resolved into a GPUBuffer as a 64-bit unsigned integer by GPUCommandEncoder.resolveQuerySet().

20.4. Timestamp Query

Timestamp queries allow applications to write timestamps to a GPUQuerySet, using:

and then resolve timestamp values (in nanoseconds as a 64-bit unsigned integer) into a GPUBuffer, using GPUCommandEncoder.resolveQuerySet().

Timestamp values are implementation-defined and may not increase monotonically. The physical device may reset the timestamp counter occasionally, which can result in unexpected values such as negative deltas between timestamps that logically should be monotonically increasing. These instances should be rare and can safely be ignored. Applications should not be written in such a way that unexpected timestamps cause an application failure.

There is a tracking vector here. Timestamp queries are implemented using high-resolution timers (see § 2.1.7.2 Device/queue-timeline timing). To mitigate security and privacy concerns, their precision must be reduced:

To get the current queue timestamp, run the following queue timeline steps:

Note: Since cross-origin isolation may not apply to the device timeline or queue timeline, crossOriginIsolatedCapability is never set to true.

Validate timestampWrites(device, timestampWrites)

Arguments:

Device timeline steps:

  1. Return true if the following requirements are met, and false if not:

21. Canvas Rendering

21.1. HTMLCanvasElement.getContext()

A GPUCanvasContext object is created via the getContext() method of an HTMLCanvasElement instance by passing the string literal 'webgpu' as its contextType argument.

Get a GPUCanvasContext from an offscreen HTMLCanvasElement:
const canvas = document.createElement('canvas');
const context = canvas.getContext('webgpu');

Unlike WebGL or 2D context creation, the second argument of HTMLCanvasElement.getContext() or OffscreenCanvas.getContext(), the context creation attribute dictionary options, is ignored. Instead, use GPUCanvasContext.configure(), which allows changing the canvas configuration without replacing the canvas.

To create a 'webgpu' context on a canvas (HTMLCanvasElement or OffscreenCanvas) canvas, run the following content timeline steps:
  1. Let context be a new GPUCanvasContext.

  2. Set context.canvas to canvas.

  3. Replace the drawing buffer of context.

  4. Return context.

Note: User agents should consider issuing developer-visible warnings when an ignored options argument is provided when calling getContext() to get a WebGPU canvas context.

21.2. GPUCanvasContext

[Exposed=(Window, Worker), SecureContext]
interface GPUCanvasContext {
    readonly attribute (HTMLCanvasElement or OffscreenCanvas) canvas;

    undefined configure(GPUCanvasConfiguration configuration);
    undefined unconfigure();

    GPUCanvasConfiguration? getConfiguration();
    GPUTexture getCurrentTexture();
};

GPUCanvasContext has the following content timeline properties:

canvas, of type (HTMLCanvasElement or OffscreenCanvas), readonly

The canvas this context was created from.

[[configuration]], of type GPUCanvasConfiguration?, initially null

The options this context is currently configured with.

null if the context has not been configured or has been unconfigured.

[[textureDescriptor]], of type GPUTextureDescriptor?, initially null

The currently configured texture descriptor, derived from the [[configuration]] and canvas.

null if the context has not been configured or has been unconfigured.

[[drawingBuffer]], an image, initially a transparent black image with the same size as the canvas

The drawing buffer is the working-copy image data of the canvas. It is exposed as writable by [[currentTexture]] (returned by getCurrentTexture()).

The drawing buffer is used to get a copy of the image contents of a context, which occurs when the canvas is displayed or otherwise read. It may be transparent, even if [[configuration]].alphaMode is "opaque". The alphaMode only affects the result of the "get a copy of the image contents of a context" algorithm.

The drawing buffer outlives the [[currentTexture]] and contains the previously-rendered contents even after the canvas has been presented. It is only cleared in Replace the drawing buffer.

Any time the drawing buffer is read, implementations must ensure that all previously submitted work (e.g. queue submissions) have completed writing to it via [[currentTexture]].

[[currentTexture]], of type GPUTexture?, initially null

The GPUTexture to draw into for the current frame. It exposes a writable view onto the underlying [[drawingBuffer]]. getCurrentTexture() populates this slot if null, then returns it.

In the steady-state of a visible canvas, any changes to the drawing buffer made through the currentTexture get presented when updating the rendering of a WebGPU canvas. At or before that point, the texture is also destroyed and [[currentTexture]] is set to to null, signalling that a new one is to be created by the next call to getCurrentTexture().

Destroying the currentTexture has no effect on the drawing buffer contents; it only terminates write-access to the drawing buffer early. During the same frame, getCurrentTexture() continues returning the same destroyed texture.

Expire the current texture sets the currentTexture to null. It is called by configure(), resizing the canvas, presentation, transferToImageBitmap(), and others.

[[lastPresentedImage]], of type (readonly image)?, initially null

The image most recently presented for this canvas in "updating the rendering of a WebGPU canvas". If the device is lost or destroyed, this image may be used as a fallback in "get a copy of the image contents of a context" in order to prevent the canvas from going blank.

Note: This property only needs to exist in implementations which implement the fallback, which is optional.

GPUCanvasContext has the following methods:

configure(configuration)

Configures the context for this canvas. This clears the drawing buffer to transparent black (in Replace the drawing buffer).

Called on: GPUCanvasContext this.

Arguments:

Arguments for the GPUCanvasContext.configure(configuration) method.
Parameter Type Nullable Optional Description
configuration GPUCanvasConfiguration Desired configuration for the context.

Returns: undefined

Content timeline steps:

  1. Let device be configuration.device.

  2. ? Validate texture format required features of configuration.format with device.[[device]].

  3. ? Validate texture format required features of each element of configuration.viewFormats with device.[[device]].

  4. If Supported context formats does not contain configuration.format, throw a TypeError.

  5. Let descriptor be the GPUTextureDescriptor for the canvas and configuration(this.canvas, configuration).

  6. Set this.[[configuration]] to configuration.

  7. Set this.[[textureDescriptor]] to descriptor.

  8. Replace the drawing buffer of this.

  9. Issue the subsequent steps on the Device timeline of device.

Device timeline steps:
  1. If any of the following requirements are unmet, generate a validation error and return.

    Note: This early validation remains valid until the next configure() call, except for validation of the size, which changes when the canvas is resized.

unconfigure()

Removes the context configuration. Destroys any textures produced while configured.

Called on: GPUCanvasContext this.

Returns: undefined

Content timeline steps:

  1. Set this.[[configuration]] to null.

  2. Set this.[[textureDescriptor]] to null.

  3. Replace the drawing buffer of this.

getConfiguration()

Returns the context configuration.

Called on: GPUCanvasContext this.

Returns: GPUCanvasConfiguration or null

Content timeline steps:

  1. Let configuration be a copy of this.[[configuration]].

  2. Return configuration.

NOTE:
In scenarios where getConfiguration() shows that toneMapping is implemented and the dynamic-range media query indicates HDR support, then WebGPU canvas should render content using the full HDR range instead of clamping values to the SDR range of the HDR display.
getCurrentTexture()

Get the GPUTexture that will be composited to the document by the GPUCanvasContext next.

NOTE:
An application should call getCurrentTexture() in the same task that renders to the canvas texture. Otherwise, the texture could get destroyed by these steps before the application is finished rendering to it.

The expiry task (defined below) is optional to implement. Even if implemented, task source priority is not normatively defined, so may happen as early as the next task, or as late as after all other task sources are empty (see automatic expiry task source). Expiry is only guaranteed when a visible canvas is displayed (updating the rendering of a WebGPU canvas) and in other callers of "Expire the current texture".

Called on: GPUCanvasContext this.

Returns: GPUTexture

Content timeline steps:

  1. If this.[[configuration]] is null, throw an InvalidStateError and return.

  2. Assert this.[[textureDescriptor]] is not null.

  3. Let device be this.[[configuration]].device.

  4. If this.[[currentTexture]] is null:

    1. Replace the drawing buffer of this.

    2. Set this.[[currentTexture]] to the result of calling device.createTexture() with this.[[textureDescriptor]], except with the GPUTexture's underlying storage pointing to this.[[drawingBuffer]].

      Note: If the texture can’t be created (e.g. due to validation failure or out-of-memory), this generates and error and returns an invalidated GPUTexture. Some validation here is redundant with that done in configure(). Implementations must not skip this redundant validation.

  5. Optionally, queue an automatic expiry task with device device and the following steps:

    1. Expire the current texture of this.

      Note: If this already happened when updating the rendering of a WebGPU canvas, it has no effect.

  6. Return this.[[currentTexture]].

Note: The same GPUTexture object will be returned by every call to getCurrentTexture() until "Expire the current texture" runs, even if that GPUTexture is destroyed, failed validation, or failed to allocate.

To get a copy of the image contents of a context:

Arguments:

Returns: image contents

Content timeline steps:

  1. Let snapshot be a transparent black image of the same size as context.canvas.

  2. Let configuration be context.[[configuration]].

  3. If configuration is null:

    1. Return snapshot.

    Note: The configuration will be null if the context has not been configured or has been unconfigured. This is identical to the behavior when the canvas has no context.

  4. Ensure that all submitted work items (e.g. queue submissions) have completed writing to the image (via context.[[currentTexture]]).

  5. If configuration.device is found to be valid:

    1. Set snapshot to a copy of the context.[[drawingBuffer]].

    Else, if context.[[lastPresentedImage]] is not null:

    1. Optionally, set snapshot to a copy of context.[[lastPresentedImage]].

      Note: This is optional because the [[lastPresentedImage]] may no longer exist, depending on what caused device loss. Implementations may choose to skip it even if do they still have access to that image.

  6. Let alphaMode be configuration.alphaMode.

  7. If alphaMode is "opaque":
    1. Clear the alpha channel of snapshot to 1.0.

    2. Tag snapshot as being opaque.

    Note: If the [[currentTexture]], if any, has been destroyed (for example in "Expire the current texture"), the alpha channel is unobservable, and implementations may clear the alpha channel in-place.

    Otherwise:

    Tag snapshot with alphaMode.

  8. Tag snapshot with the colorSpace and toneMapping of configuration.

  9. Return snapshot.

To Replace the drawing buffer of a GPUCanvasContext context, run the following content timeline steps:
  1. Expire the current texture of context.

  2. Let configuration be context.[[configuration]].

  3. Set context.[[drawingBuffer]] to a transparent black image of the same size as context.canvas.

    • If configuration is null, the drawing buffer is tagged with the color space "srgb". In this case, the drawing buffer will remain blank until the context is configured.

    • If not, the drawing buffer has the specified configuration.format and is tagged with the specified configuration.colorSpace and configuration.toneMapping.

    Note: configuration.alphaMode is ignored until "get a copy of the image contents of a context".

    NOTE:
    A newly replaced drawing buffer image behaves as if it is cleared to transparent black, but, like after "discard", an implementation can clear it lazily only if it becomes necessary.

    Note: This will often be a no-op, if the drawing buffer is already cleared and has the correct configuration.

To Expire the current texture of a GPUCanvasContext context, run the following content timeline steps:
  1. If context.[[currentTexture]] is not null:

    1. Call context.[[currentTexture]].destroy() (without destroying context.[[drawingBuffer]]) to terminate write access to the image.

    2. Set context.[[currentTexture]] to null.

21.3. HTML Specification Hooks

The following algorithms "hook" into algorithms in the HTML specification, and must run at the specified points.

When the "bitmap" is read from an HTMLCanvasElement or OffscreenCanvas with a GPUCanvasContext context, run the following content timeline steps:
  1. Return a copy of the image contents of context.

NOTE:
This occurs in many places, including:

If alphaMode is "opaque", this incurs a clear of the alpha channel. Implementations may skip this step when they are able to read or display images in a way that ignores the alpha channel.

If an application needs a canvas only for interop (not presentation), avoid "opaque" if it is not needed.

When updating the rendering of a WebGPU canvas (an HTMLCanvasElement or an OffscreenCanvas with a placeholder canvas element) with a GPUCanvasContext context, which occurs before getting the canvas’s image contents, in the following sub-steps of the event loop processing model:

Note: Service and Shared workers do not have "update the rendering" steps because they cannot render to user-visible canvases. requestAnimationFrame() is not exposed in ServiceWorkerGlobalScope and SharedWorkerGlobalScope, and OffscreenCanvases from transferControlToOffscreen() cannot be sent to these workers.

Run the following content timeline steps:

  1. Expire the current texture of context.

    Note: If this already happened in the task queued by getCurrentTexture(), it has no effect.

  2. Set context.[[lastPresentedImage]] to context.[[drawingBuffer]].

    Note: This is just a reference, not a copy; the drawing buffer’s contents can’t change in-place after the current texture has expired.

Note: This does not happen for standalone OffscreenCanvases (created by new OffscreenCanvas()).

transferToImageBitmap from WebGPU:

When transferToImageBitmap() is called on a canvas with GPUCanvasContext context, after creating an ImageBitmap from the canvas’s bitmap, run the following content timeline steps:

  1. Replace the drawing buffer of context.

Note: This makes transferToImageBitmap() equivalent to "moving" (and possibly alpha-clearing) the image contents into the ImageBitmap, without a copy.

21.4. GPUCanvasConfiguration

The supported context formats are the set of GPUTextureFormats: «"bgra8unorm", "rgba8unorm", "rgba16float"». These formats must be supported when specified as a GPUCanvasConfiguration.format regardless of the given GPUCanvasConfiguration.device.

Note: Canvas configuration cannot use srgb formats like "bgra8unorm-srgb". Instead, use the non-srgb equivalent ("bgra8unorm"), specify the srgb format in the viewFormats, and use createView() to create a view with an srgb format.

enum GPUCanvasAlphaMode {
    "opaque",
    "premultiplied",
};

enum GPUCanvasToneMappingMode {
    "standard",
    "extended",
};

dictionary GPUCanvasToneMapping {
  GPUCanvasToneMappingMode mode = "standard";
};

dictionary GPUCanvasConfiguration {
    required GPUDevice device;
    required GPUTextureFormat format;
    GPUTextureUsageFlags usage = 0x10;  // GPUTextureUsage.RENDER_ATTACHMENT
    sequence<GPUTextureFormat> viewFormats = [];
    PredefinedColorSpace colorSpace = "srgb";
    GPUCanvasToneMapping toneMapping = {};
    GPUCanvasAlphaMode alphaMode = "opaque";
};

GPUCanvasConfiguration has the following members:

device, of type GPUDevice

The GPUDevice that textures returned by getCurrentTexture() will be compatible with.

format, of type GPUTextureFormat

The format that textures returned by getCurrentTexture() will have. Must be one of the Supported context formats.

usage, of type GPUTextureUsageFlags, defaulting to 0x10

The usage that textures returned by getCurrentTexture() will have. RENDER_ATTACHMENT is the default, but is not automatically included if the usage is explicitly set. Be sure to include RENDER_ATTACHMENT when setting a custom usage if you wish to use textures returned by getCurrentTexture() as color targets for a render pass.

viewFormats, of type sequence<GPUTextureFormat>, defaulting to []

The formats that views created from textures returned by getCurrentTexture() may use.

colorSpace, of type PredefinedColorSpace, defaulting to "srgb"

The color space that values written into textures returned by getCurrentTexture() should be displayed with.

toneMapping, of type GPUCanvasToneMapping, defaulting to {}

The tone mapping determines how the content of textures returned by getCurrentTexture() are to be displayed.

alphaMode, of type GPUCanvasAlphaMode, defaulting to "opaque"

Determines the effect that alpha values will have on the content of textures returned by getCurrentTexture() when read, displayed, or used as an image source.

Configure a GPUCanvasContext to be used with a specific GPUDevice, using the preferred format for this context:
const canvas = document.createElement('canvas');
const context = canvas.getContext('webgpu');

context.configure({
    device: gpuDevice,
    format: navigator.gpu.getPreferredCanvasFormat(),
});
The GPUTextureDescriptor for the canvas and configuration( (HTMLCanvasElement or OffscreenCanvas) canvas, GPUCanvasConfiguration configuration) is a GPUTextureDescriptor with the following members:

and other members set to their defaults.

canvas.width refers to HTMLCanvasElement.width or OffscreenCanvas.width. canvas.height refers to HTMLCanvasElement.height or OffscreenCanvas.height.

21.4.1. Canvas Color Space

During presentation, the color values in the canvas are converted to the color space of the screen.

The toneMapping determines the handling of values outside of the [0, 1] interval in the color space of the screen.

21.4.2. Canvas Context sizing

All canvas configuration is set in configure() except for the resolution of the canvas, which is set by the canvas’s width and height.

Note: Like WebGL and 2d canvas, resizing a WebGPU canvas loses the current contents of the drawing buffer. In WebGPU, it does so by replacing the drawing buffer.

When an HTMLCanvasElement or OffscreenCanvas canvas with a GPUCanvasContext context has its width or height attributes set, update the canvas size by running the following content timeline steps:
  1. Replace the drawing buffer of context.

  2. Let configuration be context.[[configuration]]

  3. If configuration is not null:

    1. Set context.[[textureDescriptor]] to the GPUTextureDescriptor for the canvas and configuration(canvas, configuration).

Note: This may result in a GPUTextureDescriptor which exceeds the maxTextureDimension2D of the device. In this case, validation will fail inside getCurrentTexture().

Note: This algorithm is run any time the canvas width or height attributes are set, even if their value is not changed.

21.5. GPUCanvasToneMappingMode

This enum specifies how color values are displayed to the screen.

"standard"

Color values within the standard dynamic range of the screen are unchanged, and all other color values are projected to the standard dynamic range of the screen.

Note: This projection is often accomplished by clamping color values in the color space of the screen to the [0, 1] interval.

For example, suppose that the value (1.035, -0.175, -0.140) is written to an 'srgb' canvas.

If this is presented to an sRGB screen, then this will be converted to sRGB (which is a no-op, because the canvas is sRGB), then projected into the display’s space. Using component-wise clamping, this results in the sRGB value (1.0, 0.0, 0.0).

If this is presented to a Display P3 screen, then this will be converted to the value (0.948, 0.106, 0.01) in the Display P3 color space, and no clamping will be needed.

"extended"

Color values in the extended dynamic range of the screen are unchanged, and all other color values are projected to the extended dynamic range of the screen.

Note: This projection is often accomplished by clamping color values in the color space of the screen to the interval of values that the screen is capable of displaying, which may include values greater than 1.

For example, suppose that the value (2.5, -0.15, -0.15) is written to an 'srgb' canvas.

If this is presented to an sRGB screen that is capable of displaying values in the [0, 4] interval in sRGB space, then this will be converted to sRGB (which is a no-op, because the canvas is sRGB), then projected into the display’s space. If using component-wise clamping, this results in the sRGB value (2.5, 0.0, 0.0).

If this is presented to a Display P3 screen that is capable of displaying values in the [0, 2] interval in Display P3 space, then this will be converted to the value (2.3, 0.545, 0.386) in the Display P3 color space, then projected into the display’s space. If using component-wise clamping, this results in the Display P3 value (2.0, 0.545, 0.386).

21.6. GPUCanvasAlphaMode

This enum selects how the contents of the canvas will be interpreted when read, when displayed to the screen or used as an image source (in drawImage, toDataURL, etc.)

Below, src is a value in the canvas texture, and dst is an image that the canvas is being composited into (e.g. an HTML page rendering, or a 2D canvas).

"opaque"

Read RGB as opaque and ignore alpha values. If the content is not already opaque, the alpha channel is cleared to 1.0 in "get a copy of the image contents of a context".

"premultiplied"

Read RGBA as premultiplied: color values are premultiplied by their alpha value. 100% red at 50% alpha is [0.5, 0, 0, 0.5].

If the canvas texture contains out-of-gamut premultiplied RGBA values at the time the canvas contents are read, the behavior depends on whether the canvas is:

used as an image source

Values are preserved, as described in color space conversion.

displayed to the screen

Compositing results are undefined.

Note: This is true even if color space conversion would produce in-gamut values before compositing, because the intermediate format for compositing is not specified.

22. Errors & Debugging

During the normal course of operation of WebGPU, errors are raised via dispatch error.

After a device is [[destroy started]] or lost, errors are no longer surfaced, where possible. After this point, implementations do not need to run validation or error tracking:

22.1. Fatal Errors

enum GPUDeviceLostReason {
    "unknown",
    "destroyed",
};

[Exposed=(Window, Worker), SecureContext]
interface GPUDeviceLostInfo {
    readonly attribute GPUDeviceLostReason reason;
    readonly attribute DOMString message;
};

partial interface GPUDevice {
    readonly attribute Promise<GPUDeviceLostInfo> lost;
};

GPUDevice has the following additional attributes:

lost, of type Promise<GPUDeviceLostInfo>, readonly

A slot-backed attribute holding a promise which is created with the device, remains pending for the lifetime of the device, then resolves when the device is lost.

Upon initialization, it is set to a new promise.

22.2. GPUError

[Exposed=(Window, Worker), SecureContext]
interface GPUError {
    readonly attribute DOMString message;
};

GPUError is the base interface for all errors surfaced from popErrorScope() and the uncapturederror event.

Errors must only be generated for operations that explicitly state the conditions one may be generated under in their respective algorithms, and the subtype of error that is generated.

No errors are generated from a device which is lost or pending destruction. See § 22 Errors & Debugging.

Note: GPUError may gain new subtypes in future versions of this spec. Applications should handle this possibility, using only the error’s message when possible, and specializing using instanceof. Use error.constructor.name when it’s necessary to serialize an error (e.g. into JSON, for a debug report).

GPUError has the following immutable properties:

message, of type DOMString, readonly

A human-readable, localizable text message providing information about the error that occurred.

Note: This message is generally intended for application developers to debug their applications and capture information for debug reports, not to be surfaced to end-users.

Note: User agents should not include potentially machine-parsable details in this message, such as free system memory on "out-of-memory" or other details about the conditions under which memory was exhausted.

Note: The message should follow the best practices for language and direction information. This includes making use of any future standards which may emerge regarding the reporting of string language and direction metadata.

Editorial note: At the time of this writing, no language/direction recommendation is available that provides compatibility and consistency with legacy APIs, but when there is, adopt it formally.

[Exposed=(Window, Worker), SecureContext]
interface GPUValidationError
        : GPUError {
    constructor(DOMString message);
};

GPUValidationError is a subtype of GPUError which indicates that an operation did not satisfy all validation requirements. Validation errors are always indicative of an application error, and is expected to fail the same way across all devices assuming the same [[features]] and [[limits]] are in use.

To generate a validation error for GPUDevice device, run the following steps:

Device timeline steps:

  1. Let error be a new GPUValidationError with an appropriate error message.

  2. Dispatch error error to device.

[Exposed=(Window, Worker), SecureContext]
interface GPUOutOfMemoryError
        : GPUError {
    constructor(DOMString message);
};

GPUOutOfMemoryError is a subtype of GPUError which indicates that there was not enough free memory to complete the requested operation. The operation may succeed if attempted again with a lower memory requirement (like using smaller texture dimensions), or if memory used by other resources is released first.

To generate an out-of-memory error for GPUDevice device, run the following steps:

Device timeline steps:

  1. Let error be a new GPUOutOfMemoryError with an appropriate error message.

  2. Dispatch error error to device.

[Exposed=(Window, Worker), SecureContext]
interface GPUInternalError
        : GPUError {
    constructor(DOMString message);
};

GPUInternalError is a subtype of GPUError which indicates than an operation failed for a system or implementation-specific reason even when all validation requirements have been satisfied. For example, the operation may exceed the capabilities of the implementation in a way not easily captured by the supported limits. The same operation may succeed on other devices or under difference circumstances.

To generate an internal error for GPUDevice device, run the following steps:

Device timeline steps:

  1. Let error be a new GPUInternalError with an appropriate error message.

  2. Dispatch error error to device.

22.3. Error Scopes

A GPU error scope captures GPUErrors that were generated while the GPU error scope was current. Error scopes are used to isolate errors that occur within a set of WebGPU calls, typically for debugging purposes or to make an operation more fault tolerant.

GPU error scope has the following device timeline properties:

[[errors]], of type list<GPUError>, initially []

The GPUErrors, if any, observed while the GPU error scope was current.

[[filter]], of type GPUErrorFilter

Determines what type of GPUError this GPU error scope observes.

enum GPUErrorFilter {
    "validation",
    "out-of-memory",
    "internal",
};

partial interface GPUDevice {
    undefined pushErrorScope(GPUErrorFilter filter);
    Promise<GPUError?> popErrorScope();
};

GPUErrorFilter defines the type of errors that should be caught when calling pushErrorScope():

"validation"

Indicates that the error scope will catch a GPUValidationError.

"out-of-memory"

Indicates that the error scope will catch a GPUOutOfMemoryError.

"internal"

Indicates that the error scope will catch a GPUInternalError.

GPUDevice has the following device timeline properties:

[[errorScopeStack]], of type stack<GPU error scope>

A stack of GPU error scopes that have been pushed to the GPUDevice.

The current error scope for a GPUError error and GPUDevice device is determined by issuing the following steps to the device timeline of device:

Device timeline steps:

  1. If error is an instance of:

    GPUValidationError

    Let type be "validation".

    GPUOutOfMemoryError

    Let type be "out-of-memory".

    GPUInternalError

    Let type be "internal".

  2. Let scope be the last item of device.[[errorScopeStack]].

  3. While scope is not undefined:

    1. If scope.[[filter]] is type, return scope.

    2. Set scope to the previous item of device.[[errorScopeStack]].

  4. Return undefined.

To dispatch an error GPUError error on GPUDevice device, run the following device timeline steps:
Device timeline steps:

Note: No errors are generated from a device which is lost or pending destruction. If this algorithm is called while device.[[device]].[[destroy started]] is true or device is lost, it will not be observable to the application. See § 22 Errors & Debugging.

  1. Let scope be the current error scope for error and device.

  2. If scope is not undefined:

    1. Append error to scope.[[errors]].

    2. Return.

  3. Otherwise issue the following steps to the content timeline:

Content timeline steps:
  1. If the user agent chooses, queue a global task for GPUDevice device with the following steps:

    1. Fire a GPUUncapturedErrorEvent named "uncapturederror" on device, with an error of error.

Note: After dispatching the event, user agents should surface uncaptured errors to developers, for example as warnings in the browser’s developer console, unless the event’s defaultPrevented is true. In other words, calling preventDefault() on the event should silence the console warning.

Note: The user agent may choose to throttle or limit the number of GPUUncapturedErrorEvents that a GPUDevice can raise to prevent an excessive amount of error handling or logging from impacting performance.

pushErrorScope(filter)

Pushes a new GPU error scope onto the [[errorScopeStack]] for this.

Called on: GPUDevice this.

Arguments:

Arguments for the GPUDevice.pushErrorScope(filter) method.
Parameter Type Nullable Optional Description
filter GPUErrorFilter Which class of errors this error scope observes.

Returns: undefined

Content timeline steps:

  1. Issue the subsequent steps on the Device timeline of this.

Device timeline steps:
  1. Let scope be a new GPU error scope.

  2. Set scope.[[filter]] to filter.

  3. Push scope onto this.[[errorScopeStack]].

popErrorScope()

Pops a GPU error scope off the [[errorScopeStack]] for this and resolves to any GPUError observed by the error scope, or null if none.

There is no guarantee of the ordering of promise resolution.

Called on: GPUDevice this.

Returns: Promise<GPUError?>

Content timeline steps:

  1. Let contentTimeline be the current Content timeline.

  2. Let promise be a new promise.

  3. Issue the check steps on the Device timeline of this.

  4. Return promise.

Device timeline check steps:
  1. If this.[[device]].[[destroy started]] or this is lost:

    1. Issue the following steps on contentTimeline:

      Content timeline steps:
      1. Resolve promise with null.

    2. Return.

    Note: No errors are generated from a device which is lost or pending destruction. See § 22 Errors & Debugging.

  2. If any of the following requirements are unmet:

    Then issue the following steps on contentTimeline and return:

    Content timeline steps:
    1. Reject promise with an OperationError.

  3. Let scope be the result of popping an item off of this.[[errorScopeStack]].

  4. Let error be any one of the items in scope.[[errors]], or null if there are none.

    For any two errors E1 and E2 in the list, if E2 was caused by E1, E2 should not be the one selected.

    Note: For example, if E1 comes from t = createTexture(), and E2 comes from t.createView() because t was invalid, E1 should be be preferred since it will be easier for a developer to understand what went wrong. Since both of these are GPUValidationErrors, the only difference will be in the message field, which is meant only to be read by humans anyway.

  5. At an unspecified point now or in the future, issue the subsequent steps on contentTimeline.

    Note: By allowing popErrorScope() calls to resolve in any order, with any of the errors observed by the scope, this spec allows validation to complete out of order, as long as any state observations are made at the appropriate point in adherence to this spec. For example, this allows implementations to perform shader compilation, which depends only on non-stateful inputs, to be completed on a background thread in parallel with other device-timeline work, and report any resulting errors later.

Content timeline steps:
  1. Resolve promise with error.

Using error scopes to capture validation errors from a GPUDevice operation that may fail:
gpuDevice.pushErrorScope('validation');

let sampler = gpuDevice.createSampler({
    maxAnisotropy: 0, // Invalid, maxAnisotropy must be at least 1.
});

gpuDevice.popErrorScope().then((error) => {
    if (error) {
        // There was an error creating the sampler, so discard it.
        sampler = null;
        console.error(`An error occured while creating sampler: ${error.message}`);
    }
});
NOTE:
Error scopes can encompass as many commands as needed. The number of commands an error scope covers will generally be correlated to what sort of action the application intends to take in response to an error occuring.

For example: An error scope that only contains the creation of a single resource, such as a texture or buffer, can be used to detect failures such as out of memory conditions, in which case the application may try freeing some resources and trying the allocation again.

Error scopes do not identify which command failed, however. So, for instance, wrapping all the commands executed while loading a model in a single error scope will not offer enough granularity to determine if the issue was due to memory constraints. As a result freeing resources would usually not be a productive response to a failure of that scope. A more appropriate response would be to allow the application to fall back to a different model or produce a warning that the model could not be loaded. If responding to memory constraints is desired, the operations allocating memory can always be wrapped in a smaller nested error scope.

22.4. Telemetry

When a GPUError is generated that is not observed by any GPU error scope, the user agent may fire an event named uncapturederror at a GPUDevice using GPUUncapturedErrorEvent.

Note: uncapturederror events are intended to be used for telemetry and reporting unexpected errors. They may not be dispatched for all uncaptured errors (for example, there may be a limit on the number of errors surfaced), and should not be used for handling known error cases that may occur during normal operation of an application. Prefer using pushErrorScope() and popErrorScope() in those cases.

[Exposed=(Window, Worker), SecureContext]
interface GPUUncapturedErrorEvent : Event {
    constructor(
        DOMString type,
        GPUUncapturedErrorEventInit gpuUncapturedErrorEventInitDict
    );
    [SameObject] readonly attribute GPUError error;
};

dictionary GPUUncapturedErrorEventInit : EventInit {
    required GPUError error;
};

GPUUncapturedErrorEvent has the following attributes:

error, of type GPUError, readonly

A slot-backed attribute holding an object representing the error that was uncaptured. This has the same type as errors returned by popErrorScope().

partial interface GPUDevice {
    attribute EventHandler onuncapturederror;
};

GPUDevice has the following content timeline properties:

onuncapturederror, of type EventHandler

An event handler IDL attribute for the uncapturederror event type.

Listening for uncaptured errors from a GPUDevice:
gpuDevice.addEventListener('uncapturederror', (event) => {
    // Re-surface the error, because adding an event listener may silence console logs.
    console.error('A WebGPU error was not captured:', event.error);

    myEngineDebugReport.uncapturedErrors.push({
        type: event.error.constructor.name,
        message: event.error.message,
    });
});

23. Detailed Operations

This section describes the details of various GPU operations.

23.1. Computing

Computing operations provide direct access to GPU’s programmable hardware. Compute shaders do not have shader stage inputs or outputs; their results are side effects from writing data into storage bindings bound either as GPUBufferBindingLayout with GPUBufferBindingType "storage" or as GPUStorageTextureBindingLayout. These operations are encoded within GPUComputePassEncoder as:

The main compute algorithm:

compute(descriptor, drawCall, state)

Arguments:

  1. Let computeInvocations be an empty list.

  2. Let computeStage be descriptor.compute.

  3. Let workgroupSize be the computed workgroup size for computeStage.entryPoint after applying computeStage.constants to computeStage.module.

  4. For workgroupX in range [0, dispatchCall.workgroupCountX]:

    1. For workgroupY in range [0, dispatchCall.workgroupCountY]:

      1. For workgroupZ in range [0, dispatchCall.workgroupCountZ]:

        1. For localX in range [0, workgroupSize.x]:

          1. For localY in range [0, workgroupSize.y]:

            1. For localZ in range [0, workgroupSize.y]:

              1. Let invocation be { computeStage, workgroupX, workgroupY, workgroupZ, localX, localY, localZ }

              2. Append invocation to computeInvocations.

  5. For every invocation in computeInvocations, in any order the device chooses, including in parallel:

    1. Set the shader builtins:

      • Set the num_workgroups builtin, if any, to (
        dispatchCall.workgroupCountX,
        dispatchCall.workgroupCountY,
        dispatchCall.workgroupCountZ
        )

      • Set the workgroup_id builtin, if any, to (
        invocation.workgroupX,
        invocation.workgroupY,
        invocation.workgroupZ
        )

      • Set the local_invocation_id builtin, if any, to (
        invocation.localX,
        invocation.localY,
        invocation.localZ
        )

      • Set the global_invocation_id builtin, if any, to (
        invocation.workgroupX * workgroupSize.x + invocation.localX,
        invocation.workgroupY * workgroupSize.y + invocation.localY,
        invocation.workgroupZ * workgroupSize.z + invocation.localZ
        )
        .

      • Set the local_invocation_index builtin, if any, to invocation.localX + (invocation.localY * workgroupSize.x) + (invocation.localZ * workgroupSize.x * workgroupSize.y)

    2. Invoke the compute shader entry point described by invocation.computeStage.

Note: Shader invocations have no guaranteed order, and will generally run in parallel according to device capabilities. Developers should not assume that any given invocation or workgroup will complete before any other one is started. Some devices may appear to execute in a consistent order, but this behavior should not be relied on as it will not perform identically across all devices. Shaders that require synchronization across invocations must use Synchronization Built-in Functions to coordinate execution.

The device may become lost if shader execution does not end in a reasonable amount of time, as determined by the user agent.

23.2. Rendering

Rendering is done by a set of GPU operations that are executed within GPURenderPassEncoder, and result in modifications of the texture data, viewed by the render pass attachments. These operations are encoded with:

Note: rendering is the traditional use of GPUs, and is supported by multiple fixed-function blocks in hardware.

The main rendering algorithm:

render(pipeline, drawCall, state)

Arguments:

  1. Let descriptor be pipeline.[[descriptor]].

  2. Resolve indices. See § 23.2.1 Index Resolution.

    Let vertexList be the result of resolve indices(drawCall, state).

  3. Process vertices. See § 23.2.2 Vertex Processing.

    Execute process vertices(vertexList, drawCall, descriptor.vertex, state).

  4. Assemble primitives. See § 23.2.3 Primitive Assembly.

    Execute assemble primitives(vertexList, drawCall, descriptor.primitive).

  5. Clip primitives. See § 23.2.4 Primitive Clipping.

    Let primitiveList be the result of this stage.

  6. Rasterize. See § 23.2.5 Rasterization.

    Let rasterizationList be the result of rasterize(primitiveList, state).

  7. Process fragments. See § 23.2.6 Fragment Processing.

    Gather a list of fragments, resulting from executing process fragment(rasterPoint, descriptor, state) for each rasterPoint in rasterizationList.

  8. Write pixels. See § 23.2.7 Output Merging.

    For each non-null fragment of fragments:

23.2.1. Index Resolution

At the first stage of rendering, the pipeline builds a list of vertices to process for each instance.

resolve indices(drawCall, state)

Arguments:

Returns: list of integer indices.

  1. Let vertexIndexList be an empty list of indices.

  2. If drawCall is an indexed draw call:

    1. Initialize the vertexIndexList with drawCall.indexCount integers.

    2. For i in range 0 .. drawCall.indexCount (non-inclusive):

      1. Let relativeVertexIndex be fetch index(i + drawCall.firstIndex, state.[[index_buffer]]).

      2. If relativeVertexIndex has the special value "out of bounds", return the empty list.

        Note: Implementations may choose to display a warning when this occurs, especially when it is easy to detect (like in non-indirect indexed draw calls).

      3. Append drawCall.baseVertex + relativeVertexIndex to the vertexIndexList.

  3. Otherwise:

    1. Initialize the vertexIndexList with drawCall.vertexCount integers.

    2. Set each vertexIndexList item i to the value drawCall.firstVertex + i.

  4. Return vertexIndexList.

Note: in the case of indirect draw calls, the indexCount, vertexCount, and other properties of drawCall are read from the indirect buffer instead of the draw command itself.

fetch index(i, buffer, offset, format)

Arguments:

Returns: unsigned integer or "out of bounds"

  1. Let indexSize be defined by the state.[[index_format]]:

    "uint16"

    2

    "uint32"

    4

  2. If state.[[index_buffer_offset]] + |i + 1| × indexSize > state.[[index_buffer_size]], return the special value "out of bounds".

  3. Interpret the data in state.[[index_buffer]], starting at offset state.[[index_buffer_offset]] + i × indexSize, of size indexSize bytes, as an unsigned integer and return it.

23.2.2. Vertex Processing

Vertex processing stage is a programmable stage of the render pipeline that processes the vertex attribute data, and produces clip space positions for § 23.2.4 Primitive Clipping, as well as other data for the § 23.2.6 Fragment Processing.

process vertices(vertexIndexList, drawCall, desc, state)

Arguments:

Each vertex vertexIndex in the vertexIndexList, in each instance of index rawInstanceIndex, is processed independently. The rawInstanceIndex is in range from 0 to drawCall.instanceCount - 1, inclusive. This processing happens in parallel, and any side effects, such as writes into GPUBufferBindingType "storage" bindings, may happen in any order.

  1. Let instanceIndex be rawInstanceIndex + drawCall.firstInstance.

  2. For each non-null vertexBufferLayout in the list of desc.buffers:

    1. Let i be the index of the buffer layout in this list.

    2. Let vertexBuffer, vertexBufferOffset, and vertexBufferBindingSize be the buffer, offset, and size at slot i of state.[[vertex_buffers]].

    3. Let vertexElementIndex be dependent on vertexBufferLayout.stepMode:

      "vertex"

      vertexIndex

      "instance"

      instanceIndex

    4. Let drawCallOutOfBounds be false.

    5. For each attributeDesc in vertexBufferLayout.attributes:

      1. Let attributeOffset be vertexBufferOffset + vertexElementIndex * vertexBufferLayout.arrayStride + attributeDesc.offset.

      2. If attributeOffset + byteSize(attributeDesc.format) > vertexBufferOffset + vertexBufferBindingSize:

        1. Set drawCallOutOfBounds to true.

        2. Optionally (implementation-defined), empty vertexIndexList and return, cancelling the draw call.

          Note: This allows implementations to detect out-of-bounds values in the index buffer before issuing a draw call, instead of using invalid memory reference behavior.

    6. For each attributeDesc in vertexBufferLayout.attributes:

      1. If drawCallOutOfBounds is true:

        1. Load the attribute data according to WGSL’s invalid memory reference behavior, from vertexBuffer.

          Note: Invalid memory reference allows several behaviors, including actually loading the "correct" result for an attribute that is in-bounds, even when the draw-call-wide drawCallOutOfBounds is true.

        Otherwise:

        1. Let attributeOffset be vertexBufferOffset + vertexElementIndex * vertexBufferLayout.arrayStride + attributeDesc.offset.

        2. Load the attribute data of format attributeDesc.format from vertexBuffer starting at offset attributeOffset. The components are loaded in the order x, y, z, w from buffer memory.

      2. Convert the data into a shader-visible format, according to channel formats rules.

        An attribute of type "snorm8x2" and byte values of [0x70, 0xD0] will be converted to vec2<f32>(0.88, -0.38) in WGSL.
      3. Adjust the data size to the shader type:

        • if both are scalar, or both are vectors of the same dimensionality, no adjustment is needed.

        • if data is vector but the shader type is scalar, then only the first component is extracted.

        • if both are vectors, and data has a higher dimension, the extra components are dropped.

          An attribute of type "float32x3" and value vec3<f32>(1.0, 2.0, 3.0) will exposed to the shader as vec2<f32>(1.0, 2.0) if a 2-component vector is expected.
        • if the shader type is a vector of higher dimensionality, or the data is a scalar, then the missing components are filled from vec4<*>(0, 0, 0, 1) value.

          An attribute of type "sint32" and value 5 will be exposed to the shader as vec4<i32>(5, 0, 0, 1) if a 4-component vector is expected.
      4. Bind the data to vertex shader input location attributeDesc.shaderLocation.

  3. For each GPUBindGroup group at index in state.[[bind_groups]]:

    1. For each resource GPUBindingResource in the bind group:

      1. Let entry be the corresponding GPUBindGroupLayoutEntry for this resource.

      2. If entry.visibility includes VERTEX:

  4. Set the shader builtins:

    • Set the vertex_index builtin, if any, to vertexIndex.

    • Set the instance_index builtin, if any, to instanceIndex.

  5. Invoke the vertex shader entry point described by desc.

    Note: The target platform caches the results of vertex shader invocations. There is no guarantee that any vertexIndex that repeats more than once will result in multiple invocations. Similarly, there is no guarantee that a single vertexIndex will only be processed once.

    The device may become lost if shader execution does not end in a reasonable amount of time, as determined by the user agent.

23.2.3. Primitive Assembly

Primitives are assembled by a fixed-function stage of GPUs.

assemble primitives(vertexIndexList, drawCall, desc)

Arguments:

For each instance, the primitives get assembled from the vertices that have been processed by the shaders, based on the vertexIndexList.

  1. First, if the primitive topology is a strip, (which means that desc.stripIndexFormat is not undefined) and the drawCall is indexed, the vertexIndexList is split into sub-lists using the maximum value of desc.stripIndexFormat as a separator.

    Example: a vertexIndexList with values [1, 2, 65535, 4, 5, 6] of type "uint16" will be split in sub-lists [1, 2] and [4, 5, 6].

  2. For each of the sub-lists vl, primitive generation is done according to the desc.topology:

    "line-list"

    Line primitives are composed from (vl.0, vl.1), then (vl.2, vl.3), then (vl.4 to vl.5), etc. Each subsequent primitive takes 2 vertices.

    "line-strip"

    Line primitives are composed from (vl.0, vl.1), then (vl.1, vl.2), then (vl.2, vl.3), etc. Each subsequent primitive takes 1 vertex.

    "triangle-list"

    Triangle primitives are composed from (vl.0, vl.1, vl.2), then (vl.3, vl.4, vl.5), then (vl.6, vl.7, vl.8), etc. Each subsequent primitive takes 3 vertices.

    "triangle-strip"

    Triangle primitives are composed from (vl.0, vl.1, vl.2), then (vl.2, vl.1, vl.3), then (vl.2, vl.3, vl.4), then (vl.4, vl.3, vl.5), etc. Each subsequent primitive takes 1 vertices.

    Any incomplete primitives are dropped.

23.2.4. Primitive Clipping

Vertex shaders have to produce a built-in position (of type vec4<f32>), which denotes the clip position of a vertex in clip space coordinates.

Primitives are clipped to the clip volume, which, for any clip position p inside a primitive, is defined by the following inequalities:

When the "clip-distances" feature is enabled, this clip volume can be further restricted by user-defined half-spaces by declaring clip_distances in the output of vertex stage. Each value in the clip_distances array will be linearly interpolated across the primitive, and the portion of the primitive with interpolated distances less than 0 will be clipped.

If descriptor.primitive.unclippedDepth is true, depth clipping is not applied: the clip volume is not bounded in the z dimension.

A primitive passes through this stage unchanged if every one of its edges lie entirely inside the clip volume. If the edges of a primitives intersect the boundary of the clip volume, the intersecting edges are reconnected by new edges that lie along the boundary of the clip volume. For triangular primitives (descriptor.primitive.topology is "triangle-list" or "triangle-strip"), this reconnection may result in introduction of new vertices into the polygon, internally.

If a primitive intersects an edge of the clip volume’s boundary, the clipped polygon must include a point on this boundary edge.

If the vertex shader outputs other floating-point values (scalars and vectors), qualified with "perspective" interpolation, they also get clipped. The output values associated with a vertex that lies within the clip volume are unaffected by clipping. If a primitive is clipped, however, the output values assigned to vertices produced by clipping are clipped.

Considering an edge between vertices a and b that got clipped, resulting in the vertex c, let’s define t to be the ratio between the edge vertices: c.p = t × a.p + (1 − t) × b.p, where x.p is the output clip position of a vertex x.

For each vertex output value "v" with a corresponding fragment input, a.v and b.v would be the outputs for a and b vertices respectively. The clipped shader output c.v is produced based on the interpolation qualifier:

flat

Flat interpolation is unaffected, and is based on the provoking vertex, which is determined by the interpolation sampling mode declared in the shader. The output value is the same for the whole primitive, and matches the vertex output of the provoking vertex.

linear

The interpolation ratio gets adjusted against the perspective coordinates of the clip positions, so that the result of interpolation is linear in screen space.

perspective

The value is linearly interpolated in clip space, producing perspective-correct values.

The result of primitive clipping is a new set of primitives, which are contained within the clip volume.

23.2.5. Rasterization

Rasterization is the hardware processing stage that maps the generated primitives to the 2-dimensional rendering area of the framebuffer - the set of render attachments in the current GPURenderPassEncoder. This rendering area is split into an even grid of pixels.

The framebuffer coordinates start from the top-left corner of the render targets. Each unit corresponds exactly to one pixel. See § 3.3 Coordinate Systems for more information.

Rasterization determines the set of pixels affected by a primitive. In case of multi-sampling, each pixel is further split into descriptor.multisample.count samples. The standard sample patterns are as follows, with positions in framebuffer coordinates relative to the top-left corner of the pixel, such that the pixel ranges from (0, 0) to (1, 1):

multisample.count Sample positions
1 Sample 0: (0.5, 0.5)
4 Sample 0: (0.375, 0.125)
Sample 1: (0.875, 0.375)
Sample 2: (0.125, 0.625)
Sample 3: (0.625, 0.875)

Implementations must use the standard sample pattern for the given multisample.count when performing rasterization.

Let’s define a FragmentDestination to contain:

position

the 2D pixel position using framebuffer coordinates

sampleIndex

an integer in case § 23.2.10 Per-Sample Shading is active, or null otherwise

We’ll also use a notion of normalized device coordinates, or NDC. In this coordinate system, the viewport bounds range in X and Y from -1 to 1, and in Z from 0 to 1.

Rasterization produces a list of RasterizationPoints, each containing the following data:

destination

refers to FragmentDestination

coverageMask

refers to multisample coverage mask (see § 23.2.11 Sample Masking)

frontFacing

is true if it’s a point on the front face of a primitive

perspectiveDivisor

refers to interpolated 1.0 ÷ W across the primitive

depth

refers to the depth in viewport coordinates, i.e. between the [[viewport]] minDepth and maxDepth.

primitiveVertices

refers to the list of vertex outputs forming the primitive

barycentricCoordinates

refers to § 23.2.5.3 Barycentric coordinates

rasterize(primitiveList, state)

Arguments:

Returns: list of RasterizationPoint.

Each primitive in primitiveList is processed independently. However, the order of primitives affects later stages, such as depth/stencil operations and pixel writes.

  1. First, the clipped vertices are transformed into NDC - normalized device coordinates. Given the output position p, the NDC position and perspective divisor are:

    ndc(p) = vector(p.x ÷ p.w, p.y ÷ p.w, p.z ÷ p.w)

    divisor(p) = 1.0 ÷ p.w

  2. Let vp be state.[[viewport]]. Map the NDC position n into viewport coordinates:

    • Compute framebuffer coordinates from the render target offset and size:

      framebufferCoords(n) = vector(vp.x + 0.5 × (n.x + 1) × vp.width, vp.y + 0.5 × (−n.y + 1) × vp.height)

    • Compute depth by linearly mapping [0,1] to the viewport depth range:

      depth(n) = vp.minDepth + n.z × ( vp.maxDepth - vp.minDepth )

  3. Let rasterizationPoints be the list of points, each having its attributes (divisor(p), framebufferCoords(n), depth(n), etc.) interpolated according to its position on the primitive, using the same interpolation as § 23.2.4 Primitive Clipping. If the attribute is user-defined (not a built-in output value) then the interpolation type specified by the @interpolate WGSL attribute is used.

  4. Proceed with a specific rasterization algorithm, depending on primitive.topology:

    "point-list"

    The point, if not filtered by § 23.2.4 Primitive Clipping, goes into § 23.2.5.1 Point Rasterization.

    "line-list" or "line-strip"

    The line cut by § 23.2.4 Primitive Clipping goes into § 23.2.5.2 Line Rasterization.

    "triangle-list" or "triangle-strip"

    The polygon produced in § 23.2.4 Primitive Clipping goes into § 23.2.5.4 Polygon Rasterization.

  5. Remove all the points rp from rasterizationPoints that have rp.destination.position outside of state.[[scissorRect]].

  6. Return rasterizationPoints.

23.2.5.1. Point Rasterization

A single FragmentDestination is selected within the pixel containing the framebuffer coordinates of the point.

The coverage mask depends on multi-sampling mode:

sample-frequency

coverageMask = 1 ≪ sampleIndex

pixel-frequency multi-sampling

coverageMask = 1 ≪ descriptor.multisample.count − 1

no multi-sampling

coverageMask = 1

23.2.5.2. Line Rasterization

The exact algorithm used for line rasterization is not defined, and may differ between implementations. For example, the line may be drawn using § 23.2.5.4 Polygon Rasterization of a 1px-width rectangle around the line segment, or using Bresenham’s line algorithm to select the FragmentDestinations.

Note: See Basic Line Segment Rasterization and Bresenham Line Segment Rasterization in the Vulkan 1.4 spec for more details of how line these line rasterization algorithms may be implemented.

23.2.5.3. Barycentric coordinates

Barycentric coordinates is a list of n numbers bi, defined for a point p inside a convex polygon with n vertices vi in framebuffer space. Each bi is in range 0 to 1, inclusive, and represents the proximity to vertex vi. Their sum is always constant:

∑ (bi) = 1

These coordinates uniquely specify any point p within the polygon (or on its boundary) as:

p = ∑ (bi × pi)

For a polygon with 3 vertices - a triangle, barycentric coordinates of any point p can be computed as follows:

Apolygon = A(v1, v2, v3) b1 = A(p, b2, b3) ÷ Apolygon b2 = A(b1, p, b3) ÷ Apolygon b3 = A(b1, b2, p) ÷ Apolygon

Where A(list of points) is the area of the polygon with the given set of vertices.

For polygons with more than 3 vertices, the exact algorithm is implementation-dependent. One of the possible implementations is to triangulate the polygon and compute the barycentrics of a point based on the triangle it falls into.

23.2.5.4. Polygon Rasterization

A polygon is front-facing if it’s oriented towards the projection. Otherwise, the polygon is back-facing.

rasterize polygon()

Arguments:

Returns: list of RasterizationPoint.

  1. Let rasterizationPoints be an empty list.

  2. Let v(i) be the framebuffer coordinates for the clipped vertex number i (starting with 1) in a rasterized polygon of n vertices.

    Note: this section uses the term "polygon" instead of a "triangle", since § 23.2.4 Primitive Clipping stage may have introduced additional vertices. This is non-observable by the application.

  3. Determine if the polygon is front-facing, which depends on the sign of the area occupied by the polygon in framebuffer coordinates:

    area = 0.5 × ((v1.x × vn.y − vn.x × v1.y) + ∑ (vi+1.x × vi.y − vi.x × vi+1.y))

    The sign of area is interpreted based on the primitive.frontFace:

    "ccw"

    area > 0 is considered front-facing, otherwise back-facing

    "cw"

    area < 0 is considered front-facing, otherwise back-facing

  4. Cull based on primitive.cullMode:

    "none"

    All polygons pass this test.

    "front"

    The front-facing polygons are discarded, and do not process in later stages of the render pipeline.

    "back"

    The back-facing polygons are discarded.

  5. Determine a set of fragments inside the polygon in framebuffer space - these are locations scheduled for the per-fragment operations. This operation is known as "point sampling". The logic is based on descriptor.multisample:

    disabled

    Fragments are associated with pixel centers. That is, all the points with coordinates C, where fract(C) = vector2(0.5, 0.5) in the framebuffer space, enclosed into the polygon, are included. If a pixel center is on the edge of the polygon, whether or not it’s included is not defined.

    Note: this becomes a subject of precision for the rasterizer.

    enabled

    Each pixel is associated with descriptor.multisample.count locations, which are implementation-defined. The locations are ordered, and the list is the same for each pixel of the framebuffer. Each location corresponds to one fragment in the multisampled framebuffer.

    The rasterizer builds a mask of locations being hit inside each pixel and provides is as "sample-mask" built-in to the fragment shader.

  6. For each produced fragment of type FragmentDestination:

    1. Let rp be a new RasterizationPoint object

    2. Compute the list b as § 23.2.5.3 Barycentric coordinates of that fragment. Set rp.barycentricCoordinates to b.

    3. Let di be the depth value of vi.

    4. Set rp.depth to ∑ (bi × di)

    5. Append rp to rasterizationPoints.

  7. Return rasterizationPoints.

23.2.6. Fragment Processing

The fragment processing stage is a programmable stage of the render pipeline that computes the fragment data (often a color) to be written into render targets.

This stage produces a Fragment for each RasterizationPoint:

process fragment(rp, descriptor, state)

Arguments:

Returns: Fragment or null.

  1. Let fragmentDesc be descriptor.fragment.

  2. Let depthStencilDesc be descriptor.depthStencil.

  3. Let fragment be a new Fragment object.

  4. Set fragment.destination to rp.destination.

  5. Set fragment.frontFacing to rp.frontFacing.

  6. Set fragment.coverageMask to rp.coverageMask.

  7. Set fragment.depth to rp.depth.

  8. If frag_depth builtin is not produced by the shader:

    1. Set fragment.depthPassed to the result of compare fragment(fragment.destination, fragment.depth, "depth", state.[[depthStencilAttachment]], depthStencilDesc?.depthCompare).

  9. Set stencilState to depthStencilDesc?.stencilFront if rp.frontFacing is true and depthStencilDesc?.stencilBack otherwise.

  10. Set fragment.stencilPassed to the result of compare fragment(fragment.destination, state.[[stencilReference]], "stencil", state.[[depthStencilAttachment]], stencilState?.compare).

  11. If fragmentDesc is not null:

    1. If fragment.depthPassed is false, the frag_depth builtin is not produced by the shader entry point, and the shader entry point does not write to any storage bindings, the following steps may be skipped.

    2. Set the shader input builtins. For each non-composite argument of the entry point, annotated as a builtin, set its value based on the annotation:

      position

      vec4<f32>(rp.destination.position, rp.depth, rp.perspectiveDivisor)

      front_facing

      rp.frontFacing

      sample_index

      rp.destination.sampleIndex

      sample_mask

      rp.coverageMask

    3. For each user-specified shader stage input of the fragment stage:

      1. Let value be the interpolated fragment input, based on rp.barycentricCoordinates, rp.primitiveVertices, and the interpolation qualifier on the input.

      2. Set the corresponding fragment shader location input to value.

    4. Invoke the fragment shader entry point described by fragmentDesc.

      The device may become lost if shader execution does not end in a reasonable amount of time, as determined by the user agent.

    5. If the fragment issued discard, return null.

    6. Set fragment.colors to the user-specified shader stage output values from the shader.

    7. Take the shader output builtins:

      1. If frag_depth builtin is produced by the shader as value:

        1. Let vp be state.[[viewport]].

        2. Set fragment.depth to clamp(value, vp.minDepth, vp.maxDepth).

        3. Set fragment.depthPassed to the result of compare fragment(fragment.destination, fragment.depth, "depth", state.[[depthStencilAttachment]], depthStencilDesc?.depthCompare).

    8. If sample_mask builtin is produced by the shader as value:

      1. Set fragment.coverageMask to fragment.coverageMaskvalue.

    Otherwise we are in § 23.2.8 No Color Output mode, and fragment.colors is empty.

  12. Return fragment.

compare fragment(destination, value, aspect, attachment, compareFunc)

Arguments:

Returns: true if the comparison passes, or false otherwise

Processing of fragments happens in parallel, while any side effects, such as writes into GPUBufferBindingType "storage" bindings, may happen in any order.

23.2.7. Output Merging

Output merging is a fixed-function stage of the render pipeline that outputs the fragment color, depth and stencil data to be written into the render pass attachments.

process depth stencil(fragment, pipeline, state)

Arguments:

  1. Let depthStencilDesc be pipeline.[[descriptor]].depthStencil.

  2. If pipeline.[[writesDepth]] is true and fragment.depthPassed is true:

    1. Set the value of the depth aspect of state.[[depthStencilAttachment]] at fragment.destination to fragment.depth.

  3. If pipeline.[[writesStencil]] is true:

    1. Set stencilState to depthStencilDesc.stencilFront if fragment.frontFacing is true and depthStencilDesc.stencilBack otherwise.

    2. If fragment.stencilPassed is false:

      • Let stencilOp be stencilState.failOp.

      Else if fragment.depthPassed is false:

      Else:

      • Let stencilOp be stencilState.passOp.

    3. Update the value of the stencil aspect of state.[[depthStencilAttachment]] at fragment.destination by performing the operation described by stencilOp.

The depth input to this stage, if any, is clamped to the current [[viewport]] depth range (regardless of whether the fragment shader stage writes the frag_depth builtin).

process color attachments(fragment, pipeline, state)

Arguments:

  1. If fragment.depthPassed is false or fragment.stencilPassed is false, return.

  2. Let targets be pipeline.[[descriptor]].fragment.targets.

  3. For each attachment of state.[[colorAttachments]]:

    1. Let color be the value from fragment.colors that corresponds with attachment.

    2. Let targetDesc be the targets entry that corresponds with attachment.

    3. If targetDesc.blend is provided:

      1. Let colorBlend be targetDesc.blend.color.

      2. Let alphaBlend be targetDesc.blend.alpha.

      3. Set the RGB components of color to the value computed by performing the operation described by colorBlend.operation with the values described by colorBlend.srcFactor and colorBlend.dstFactor.

      4. Set the alpha component of color to the value computed by performing the operation described by alphaBlend.operation with the values described by alphaBlend.srcFactor and alphaBlend.dstFactor.

    4. Set the value of attachment at fragment.destination to color.

23.2.8. No Color Output

In no-color-output mode, pipeline does not produce any color attachment outputs.

The pipeline still performs rasterization and produces depth values based on the vertex position output. The depth testing and stencil operations can still be used.

23.2.9. Alpha to Coverage

In alpha-to-coverage mode, an additional alpha-to-coverage mask of MSAA samples is generated based on the alpha component of the fragment shader output value at @location(0).

The algorithm of producing the extra mask is platform-dependent and can vary for different pixels. It guarantees that:

23.2.10. Per-Sample Shading

When rendering into multisampled render attachments, fragment shaders can be run once per-pixel or once per-sample. Fragment shaders must run once per-sample if either the sample_index builtin or sample interpolation sampling is used and contributes to the shader output. Otherwise fragment shaders may run once per-pixel with the result broadcast out to each of the samples included in the final sample mask.

When using per-sample shading, the color output for sample N is produced by the fragment shader execution with sample_index == N for the current pixel.

23.2.11. Sample Masking

The final sample mask for a pixel is computed as: rasterization mask & mask & shader-output mask.

Only the lower count bits of the mask are considered.

If the least-significant bit at position N of the final sample mask has value of "0", the sample color outputs (corresponding to sample N) to all attachments of the fragment shader are discarded. Also, no depth test or stencil operations are executed on the relevant samples of the depth-stencil attachment.

The rasterization mask is produced by the rasterization stage, based on the shape of the rasterized polygon. The samples included in the shape get the relevant bits 1 in the mask.

The shader-output mask takes the output value of "sample_mask" builtin in the fragment shader. If the builtin is not output from the fragment shader, and alphaToCoverageEnabled is enabled, the shader-output mask becomes the alpha-to-coverage mask. Otherwise, it defaults to 0xFFFFFFFF.

24. Type Definitions

typedef [EnforceRange] unsigned long GPUBufferDynamicOffset;
typedef [EnforceRange] unsigned long GPUStencilValue;
typedef [EnforceRange] unsigned long GPUSampleMask;
typedef [EnforceRange] long GPUDepthBias;

typedef [EnforceRange] unsigned long long GPUSize64;
typedef [EnforceRange] unsigned long GPUIntegerCoordinate;
typedef [EnforceRange] unsigned long GPUIndex32;
typedef [EnforceRange] unsigned long GPUSize32;
typedef [EnforceRange] long GPUSignedOffset32;

typedef unsigned long long GPUSize64Out;
typedef unsigned long GPUIntegerCoordinateOut;
typedef unsigned long GPUSize32Out;

typedef unsigned long GPUFlagsConstant;

24.1. Colors & Vectors

dictionary GPUColorDict {
    required double r;
    required double g;
    required double b;
    required double a;
};
typedef (sequence<double> or GPUColorDict) GPUColor;

Note: double is large enough to precisely hold 32-bit signed/unsigned integers and single-precision floats.

r, of type double

The red channel value.

g, of type double

The green channel value.

b, of type double

The blue channel value.

a, of type double

The alpha channel value.

For a given GPUColor value color, depending on its type, the syntax:
validate GPUColor shape(color)

Arguments:

Returns: undefined

Content timeline steps:

  1. Throw a TypeError if color is a sequence and color.size ≠ 4.

dictionary GPUOrigin2DDict {
    GPUIntegerCoordinate x = 0;
    GPUIntegerCoordinate y = 0;
};
typedef (sequence<GPUIntegerCoordinate> or GPUOrigin2DDict) GPUOrigin2D;
For a given GPUOrigin2D value origin, depending on its type, the syntax:
validate GPUOrigin2D shape(origin)

Arguments:

Returns: undefined

Content timeline steps:

  1. Throw a TypeError if origin is a sequence and origin.size > 2.

dictionary GPUOrigin3DDict {
    GPUIntegerCoordinate x = 0;
    GPUIntegerCoordinate y = 0;
    GPUIntegerCoordinate z = 0;
};
typedef (sequence<GPUIntegerCoordinate> or GPUOrigin3DDict) GPUOrigin3D;
For a given GPUOrigin3D value origin, depending on its type, the syntax:
validate GPUOrigin3D shape(origin)

Arguments:

Returns: undefined

Content timeline steps:

  1. Throw a TypeError if origin is a sequence and origin.size > 3.

dictionary GPUExtent3DDict {
    required GPUIntegerCoordinate width;
    GPUIntegerCoordinate height = 1;
    GPUIntegerCoordinate depthOrArrayLayers = 1;
};
typedef (sequence<GPUIntegerCoordinate> or GPUExtent3DDict) GPUExtent3D;
width, of type GPUIntegerCoordinate

The width of the extent.

height, of type GPUIntegerCoordinate, defaulting to 1

The height of the extent.

depthOrArrayLayers, of type GPUIntegerCoordinate, defaulting to 1

The depth of the extent or the number of array layers it contains. If used with a GPUTexture with a GPUTextureDimension of "3d" defines the depth of the texture. If used with a GPUTexture with a GPUTextureDimension of "2d" defines the number of array layers in the texture.

For a given GPUExtent3D value extent, depending on its type, the syntax:
validate GPUExtent3D shape(extent)

Arguments:

Returns: undefined

Content timeline steps:

  1. Throw a TypeError if:

25. Feature Index

25.1. "depth-clip-control"

Allows depth clipping to be disabled.

This feature adds the following optional API surfaces:

25.2. "depth32float-stencil8"

Allows for explicit creation of textures of format "depth32float-stencil8".

This feature adds the following optional API surfaces:

25.3. "texture-compression-bc"

Allows for explicit creation of textures of BC compressed formats. Only supports 2D textures.

Note: Adapters which support either "texture-compression-bc" or "texture-compression-bc-sliced-3d" always support both, even though they are separate features. To use "texture-compression-bc-sliced-3d", enable it separately.

This feature adds the following optional API surfaces:

25.4. "texture-compression-bc-sliced-3d"

Allows the 3d dimension for textures with BC compressed formats.

Note: Adapters which support either "texture-compression-bc" or "texture-compression-bc-sliced-3d" always support both, even though they are separate features. To use "texture-compression-bc-sliced-3d", both must be enabled explicitly as this feature does not enable the BC formats.

This feature adds no optional API surfaces.

25.5. "texture-compression-etc2"

Allows for explicit creation of textures of ETC2 compressed formats. Only supports 2D textures.

This feature adds the following optional API surfaces:

25.6. "texture-compression-astc"

Allows for explicit creation of textures of ASTC compressed formats. Only supports 2D textures.

This feature adds the following optional API surfaces:

25.7. "texture-compression-astc-sliced-3d"

Allows the 3d dimension for textures with ASTC compressed formats.

Note: Adapters which support "texture-compression-astc" do not always support "texture-compression-astc-sliced-3d". To use "texture-compression-astc-sliced-3d", "texture-compression-astc" must be enabled explicitly as this feature does not enable the ASTC formats.

This feature adds no optional API surfaces.

25.8. "timestamp-query"

Adds the ability to query timestamps from GPU command buffers. See § 20.4 Timestamp Query.

This feature adds the following optional API surfaces:

25.9. "indirect-first-instance"

Allows the use of non-zero firstInstance values in indirect draw parameters and indirect drawIndexed parameters.

This feature adds no optional API surfaces.

25.10. "shader-f16"

Allows the use of the half-precision floating-point type f16 in WGSL.

This feature adds the following optional API surfaces:

25.11. "rg11b10ufloat-renderable"

Allows the RENDER_ATTACHMENT usage on textures with format "rg11b10ufloat", and also allows textures of that format to be blended and multisampled.

This feature adds no optional API surfaces.

25.12. "bgra8unorm-storage"

Allows the STORAGE_BINDING usage on textures with format "bgra8unorm".

This feature adds no optional API surfaces.

25.13. "float32-filterable"

Makes textures with formats "r32float", "rg32float", and "rgba32float" filterable.

25.14. "float32-blendable"

Makes textures with formats "r32float", "rg32float", and "rgba32float" blendable.

25.15. "clip-distances"

Allows the use of clip_distances in WGSL.

This feature adds the following optional API surfaces:

25.16. "dual-source-blending"

Allows the use of blend_src in WGSL and simultaneously using both pixel shader outputs (@blend_src(0) and @blend_src(1)) as inputs to a blending operation with the single color attachment at location 0.

This feature adds the following optional API surfaces:

26. Appendices

26.1. Texture Format Capabilities

26.1.1. Plain color formats

All plain color formats support COPY_SRC, COPY_DST, and TEXTURE_BINDING usage. Additionally, all plain color formats support textures with "3d" dimension.

The RENDER_ATTACHMENT and STORAGE_BINDING columns specify support for GPUTextureUsage.RENDER_ATTACHMENT and GPUTextureUsage.STORAGE_BINDING usage respectively.

The render target pixel byte cost and render target component alignment are used to validate the maxColorAttachmentBytesPerSample limit.

Note: The texel block memory cost of each of these formats is the same as its texel block copy footprint.

Format GPUTextureSampleType RENDER_ATTACHMENT blendable multisampling resolve STORAGE_BINDING Texel block copy footprint (Bytes) Render target pixel byte cost (Bytes)
"write-only" "read-only" "read-write"
8 bits per component (1-byte render target component alignment)
r8unorm "float",
"unfilterable-float"
1
r8snorm "float",
"unfilterable-float"
1
r8uint "uint" 1
r8sint "sint" 1
rg8unorm "float",
"unfilterable-float"
2
rg8snorm "float",
"unfilterable-float"
2
rg8uint "uint" 2
rg8sint "sint" 2
rgba8unorm "float",
"unfilterable-float"
4 8
rgba8unorm-srgb "float",
"unfilterable-float"
4 8
rgba8snorm "float",
"unfilterable-float"
4
rgba8uint "uint" 4
rgba8sint "sint" 4
bgra8unorm "float",
"unfilterable-float"
If "bgra8unorm-storage" is enabled 4 8
bgra8unorm-srgb "float",
"unfilterable-float"
4 8
16 bits per component (2-byte render target component alignment)
r16uint "uint" 2
r16sint "sint" 2
r16float "float",
"unfilterable-float"
2
rg16uint "uint" 4
rg16sint "sint" 4
rg16float "float",
"unfilterable-float"
4
rgba16uint "uint" 8
rgba16sint "sint" 8
rgba16float "float",
"unfilterable-float"
8
32 bits per component (4-byte render target component alignment)
r32uint "uint" 4
r32sint "sint" 4
r32float "unfilterable-float" If "float32-blendable" is enabled 4
rg32uint "uint" 8
rg32sint "sint" 8
rg32float "unfilterable-float" If "float32-blendable" is enabled 8
rgba32uint "uint" 16
rgba32sint "sint" 16
rgba32float "unfilterable-float" If "float32-blendable" is enabled 16
mixed component width, 32 bits per texel (4-byte render target component alignment)
rgb10a2uint "uint" 4 8
rgb10a2unorm "float",
"unfilterable-float"
4 8
rg11b10ufloat "float",
"unfilterable-float"
If "rg11b10ufloat-renderable" is enabled 4 8

26.1.2. Depth-stencil formats

A depth-or-stencil format is any format with depth and/or stencil aspects. A combined depth-stencil format is a depth-or-stencil format that has both depth and stencil aspects.

All depth-or-stencil formats support the COPY_SRC, COPY_DST, TEXTURE_BINDING, and RENDER_ATTACHMENT usages. All of these formats support multisampling. However, certain copy operations also restrict the source and destination formats, and none of these formats support textures with "3d" dimension.

Depth textures cannot be used with "filtering" samplers, but can always be used with "comparison" samplers even if they use filtering.

Format
NOTE:
Texel block memory cost (Bytes)
Aspect GPUTextureSampleType Valid texel copy source Valid texel copy destination Texel block copy footprint (Bytes) Aspect-specific format
stencil8 1 − 4 stencil "uint" 1 stencil8
depth16unorm 2 depth "depth", "unfilterable-float" 2 depth16unorm
depth24plus 4 depth "depth", "unfilterable-float" depth24plus
depth24plus-stencil8 4 − 8 depth "depth", "unfilterable-float" depth24plus
stencil "uint" 1 stencil8
depth32float 4 depth "depth", "unfilterable-float" 4 depth32float
depth32float-stencil8 5 − 8 depth "depth", "unfilterable-float" 4 depth32float
stencil "uint" 1 stencil8

24-bit depth refers to a 24-bit unsigned normalized depth format with a range from 0.0 to 1.0, which would be spelled "depth24unorm" if exposed.

26.1.2.1. Reading and Sampling Depth/Stencil Textures

It is possible to bind a depth-aspect GPUTextureView to either a texture_depth_* binding or a binding with other non-depth 2d/cube texture types.

A stencil-aspect GPUTextureView must be bound to a normal texture binding type. The sampleType in the GPUBindGroupLayout must be "uint".

Reading or sampling the depth or stencil aspect of a texture behaves as if the texture contains the values (V, X, X, X), where V is the actual depth or stencil value, and each X is an implementation-defined unspecified value.

For depth-aspect bindings, the unspecified values are not visible through bindings with texture_depth_* types.

If a depth texture is bound to tex with type texture_2d<f32>:

Note: Short of adding a new more constrained stencil sampler type (like depth), it’s infeasible for implementations to efficiently paper over the driver differences for depth/stencil reads. As this was not a portability pain point for WebGL, it’s not expected to be problematic in WebGPU. In practice, expect either (V, V, V, V) or (V, 0, 0, 1) (where V is the depth or stencil value), depending on hardware.

26.1.2.2. Copying Depth/Stencil Textures

The depth aspects of depth32float formats ("depth32float" and "depth32float-stencil8" have a limited range. As a result, copies into such textures are only valid from other textures of the same format.

The depth aspects of depth24plus formats ("depth24plus" and "depth24plus-stencil8") have opaque representations (implemented as either 24-bit depth or "depth32float"). As a result, depth-aspect texel copies are not allowed with these formats.

NOTE:
It is possible to imitate these disallowed copies:

26.1.3. Packed formats

All packed texture formats support COPY_SRC, COPY_DST, and TEXTURE_BINDING usages. All of these formats are filterable. None of these formats are renderable or support multisampling.

A compressed format is any format with a block size greater than 1×1.

Note: The texel block memory cost of each of these formats is the same as its texel block copy footprint.

Format Texel block copy footprint (Bytes) GPUTextureSampleType Texel block width/height "3d" Feature
rgb9e5ufloat 4 "float",
"unfilterable-float"
1 × 1
bc1-rgba-unorm 8 "float",
"unfilterable-float"
4 × 4 If "texture-compression-bc-sliced-3d" is enabled texture-compression-bc
bc1-rgba-unorm-srgb
bc2-rgba-unorm 16
bc2-rgba-unorm-srgb
bc3-rgba-unorm 16
bc3-rgba-unorm-srgb
bc4-r-unorm 8
bc4-r-snorm
bc5-rg-unorm 16
bc5-rg-snorm
bc6h-rgb-ufloat 16
bc6h-rgb-float
bc7-rgba-unorm 16
bc7-rgba-unorm-srgb
etc2-rgb8unorm 8 "float",
"unfilterable-float"
4 × 4 texture-compression-etc2
etc2-rgb8unorm-srgb
etc2-rgb8a1unorm 8
etc2-rgb8a1unorm-srgb
etc2-rgba8unorm 16
etc2-rgba8unorm-srgb
eac-r11unorm 8
eac-r11snorm
eac-rg11unorm 16
eac-rg11snorm
astc-4x4-unorm 16 "float",
"unfilterable-float"
4 × 4 If "texture-compression-astc-sliced-3d" is enabled texture-compression-astc
astc-4x4-unorm-srgb
astc-5x4-unorm 16 5 × 4
astc-5x4-unorm-srgb
astc-5x5-unorm 16 5 × 5
astc-5x5-unorm-srgb
astc-6x5-unorm 16 6 × 5
astc-6x5-unorm-srgb
astc-6x6-unorm 16 6 × 6
astc-6x6-unorm-srgb
astc-8x5-unorm 16 8 × 5
astc-8x5-unorm-srgb
astc-8x6-unorm 16 8 × 6
astc-8x6-unorm-srgb
astc-8x8-unorm 16 8 × 8
astc-8x8-unorm-srgb
astc-10x5-unorm 16 10 × 5
astc-10x5-unorm-srgb
astc-10x6-unorm 16 10 × 6
astc-10x6-unorm-srgb
astc-10x8-unorm 16 10 × 8
astc-10x8-unorm-srgb
astc-10x10-unorm 16 10 × 10
astc-10x10-unorm-srgb
astc-12x10-unorm 16 12 × 10
astc-12x10-unorm-srgb
astc-12x12-unorm 16 12 × 12
astc-12x12-unorm-srgb

Conformance

Document conventions

Conformance requirements are expressed with a combination of descriptive assertions and RFC 2119 terminology. The key words “MUST”, “MUST NOT”, “REQUIRED”, “SHALL”, “SHALL NOT”, “SHOULD”, “SHOULD NOT”, “RECOMMENDED”, “MAY”, and “OPTIONAL” in the normative parts of this document are to be interpreted as described in RFC 2119. However, for readability, these words do not appear in all uppercase letters in this specification.

All of the text of this specification is normative except sections explicitly marked as non-normative, examples, and notes. [RFC2119]

Examples in this specification are introduced with the words “for example” or are set apart from the normative text with class="example", like this:

This is an example of an informative example.

Informative notes begin with the word “Note” and are set apart from the normative text with class="note", like this:

Note, this is an informative note.

Conformant Algorithms

Requirements phrased in the imperative as part of algorithms (such as "strip any leading space characters" or "return false and abort these steps") are to be interpreted with the meaning of the key word ("must", "should", "may", etc) used in introducing the algorithm.

Conformance requirements phrased as algorithms or specific steps can be implemented in any manner, so long as the end result is equivalent. In particular, the algorithms defined in this specification are intended to be easy to understand and are not intended to be performant. Implementers are encouraged to optimize.

Index

Terms defined by this specification

Terms defined by reference

References

Normative References

[DOM]
Anne van Kesteren. DOM Standard. Living Standard. URL: https://dom.spec.whatwg.org/
[ECMASCRIPT]
ECMAScript Language Specification. URL: https://tc39.es/ecma262/multipage/
[HR-TIME-3]
Yoav Weiss. High Resolution Time. 7 November 2024. WD. URL: https://www.w3.org/TR/hr-time-3/
[HTML]
Anne van Kesteren; et al. HTML Standard. Living Standard. URL: https://html.spec.whatwg.org/multipage/
[I18N-GLOSSARY]
Richard Ishida; Addison Phillips. Internationalization Glossary. 17 October 2024. NOTE. URL: https://www.w3.org/TR/i18n-glossary/
[INFRA]
Anne van Kesteren; Domenic Denicola. Infra Standard. Living Standard. URL: https://infra.spec.whatwg.org/
[RFC2119]
S. Bradner. Key words for use in RFCs to Indicate Requirement Levels. March 1997. Best Current Practice. URL: https://datatracker.ietf.org/doc/html/rfc2119
[WEBCODECS]
Paul Adenot; Bernard Aboba; Eugene Zemtsov. WebCodecs. 12 December 2024. WD. URL: https://www.w3.org/TR/webcodecs/
[WEBGL-1]
Dean Jackson; Jeff Gilbert. WebGL Specification, Version 1.0. 9 August 2017. URL: https://registry.khronos.org/webgl/specs/latest/1.0/
[WEBIDL]
Edgar Chen; Timothy Gu. Web IDL Standard. Living Standard. URL: https://webidl.spec.whatwg.org/
[WGSL]
Alan Baker; Mehmet Oguz Derin; David Neto. WebGPU Shading Language. 19 December 2024. Candidate Recommendation. URL: https://www.w3.org/TR/WGSL/

Informative References

[MEDIAQUERIES-5]
Dean Jackson; et al. Media Queries Level 5. 18 December 2021. WD. URL: https://www.w3.org/TR/mediaqueries-5/
[SERVICE-WORKERS]
Jake Archibald; Marijn Kruisselbrink. Service Workers. 12 July 2022. CR. URL: https://www.w3.org/TR/service-workers/
[VULKAN]
The Khronos Vulkan Working Group. Vulkan 1.4. URL: https://registry.khronos.org/vulkan/specs/latest/html/vkspec.html

IDL Index

interface mixin GPUObjectBase {
    attribute USVString label;
};

dictionary GPUObjectDescriptorBase {
    USVString label = "";
};

[Exposed=(Window, Worker), SecureContext]
interface GPUSupportedLimits {
    readonly attribute unsigned long maxTextureDimension1D;
    readonly attribute unsigned long maxTextureDimension2D;
    readonly attribute unsigned long maxTextureDimension3D;
    readonly attribute unsigned long maxTextureArrayLayers;
    readonly attribute unsigned long maxBindGroups;
    readonly attribute unsigned long maxBindGroupsPlusVertexBuffers;
    readonly attribute unsigned long maxBindingsPerBindGroup;
    readonly attribute unsigned long maxDynamicUniformBuffersPerPipelineLayout;
    readonly attribute unsigned long maxDynamicStorageBuffersPerPipelineLayout;
    readonly attribute unsigned long maxSampledTexturesPerShaderStage;
    readonly attribute unsigned long maxSamplersPerShaderStage;
    readonly attribute unsigned long maxStorageBuffersPerShaderStage;
    readonly attribute unsigned long maxStorageTexturesPerShaderStage;
    readonly attribute unsigned long maxUniformBuffersPerShaderStage;
    readonly attribute unsigned long long maxUniformBufferBindingSize;
    readonly attribute unsigned long long maxStorageBufferBindingSize;
    readonly attribute unsigned long minUniformBufferOffsetAlignment;
    readonly attribute unsigned long minStorageBufferOffsetAlignment;
    readonly attribute unsigned long maxVertexBuffers;
    readonly attribute unsigned long long maxBufferSize;
    readonly attribute unsigned long maxVertexAttributes;
    readonly attribute unsigned long maxVertexBufferArrayStride;
    readonly attribute unsigned long maxInterStageShaderVariables;
    readonly attribute unsigned long maxColorAttachments;
    readonly attribute unsigned long maxColorAttachmentBytesPerSample;
    readonly attribute unsigned long maxComputeWorkgroupStorageSize;
    readonly attribute unsigned long maxComputeInvocationsPerWorkgroup;
    readonly attribute unsigned long maxComputeWorkgroupSizeX;
    readonly attribute unsigned long maxComputeWorkgroupSizeY;
    readonly attribute unsigned long maxComputeWorkgroupSizeZ;
    readonly attribute unsigned long maxComputeWorkgroupsPerDimension;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUSupportedFeatures {
    readonly setlike<DOMString>;
};

[Exposed=(Window, Worker), SecureContext]
interface WGSLLanguageFeatures {
    readonly setlike<DOMString>;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUAdapterInfo {
    readonly attribute DOMString vendor;
    readonly attribute DOMString architecture;
    readonly attribute DOMString device;
    readonly attribute DOMString description;
};

interface mixin NavigatorGPU {
    [SameObject, SecureContext] readonly attribute GPU gpu;
};
Navigator includes NavigatorGPU;
WorkerNavigator includes NavigatorGPU;

[Exposed=(Window, Worker), SecureContext]
interface GPU {
    Promise<GPUAdapter?> requestAdapter(optional GPURequestAdapterOptions options = {});
    GPUTextureFormat getPreferredCanvasFormat();
    [SameObject] readonly attribute WGSLLanguageFeatures wgslLanguageFeatures;
};

dictionary GPURequestAdapterOptions {
    DOMString featureLevel = "core";
    GPUPowerPreference powerPreference;
    boolean forceFallbackAdapter = false;
};

enum GPUPowerPreference {
    "low-power",
    "high-performance",
};

[Exposed=(Window, Worker), SecureContext]
interface GPUAdapter {
    [SameObject] readonly attribute GPUSupportedFeatures features;
    [SameObject] readonly attribute GPUSupportedLimits limits;
    [SameObject] readonly attribute GPUAdapterInfo info;
    readonly attribute boolean isFallbackAdapter;

    Promise<GPUDevice> requestDevice(optional GPUDeviceDescriptor descriptor = {});
};

dictionary GPUDeviceDescriptor
         : GPUObjectDescriptorBase {
    sequence<GPUFeatureName> requiredFeatures = [];
    record<DOMString, (GPUSize64 or undefined)> requiredLimits = {};
    GPUQueueDescriptor defaultQueue = {};
};

enum GPUFeatureName {
    "depth-clip-control",
    "depth32float-stencil8",
    "texture-compression-bc",
    "texture-compression-bc-sliced-3d",
    "texture-compression-etc2",
    "texture-compression-astc",
    "texture-compression-astc-sliced-3d",
    "timestamp-query",
    "indirect-first-instance",
    "shader-f16",
    "rg11b10ufloat-renderable",
    "bgra8unorm-storage",
    "float32-filterable",
    "float32-blendable",
    "clip-distances",
    "dual-source-blending",
};

[Exposed=(Window, Worker), SecureContext]
interface GPUDevice : EventTarget {
    [SameObject] readonly attribute GPUSupportedFeatures features;
    [SameObject] readonly attribute GPUSupportedLimits limits;

    [SameObject] readonly attribute GPUQueue queue;

    undefined destroy();

    GPUBuffer createBuffer(GPUBufferDescriptor descriptor);
    GPUTexture createTexture(GPUTextureDescriptor descriptor);
    GPUSampler createSampler(optional GPUSamplerDescriptor descriptor = {});
    GPUExternalTexture importExternalTexture(GPUExternalTextureDescriptor descriptor);

    GPUBindGroupLayout createBindGroupLayout(GPUBindGroupLayoutDescriptor descriptor);
    GPUPipelineLayout createPipelineLayout(GPUPipelineLayoutDescriptor descriptor);
    GPUBindGroup createBindGroup(GPUBindGroupDescriptor descriptor);

    GPUShaderModule createShaderModule(GPUShaderModuleDescriptor descriptor);
    GPUComputePipeline createComputePipeline(GPUComputePipelineDescriptor descriptor);
    GPURenderPipeline createRenderPipeline(GPURenderPipelineDescriptor descriptor);
    Promise<GPUComputePipeline> createComputePipelineAsync(GPUComputePipelineDescriptor descriptor);
    Promise<GPURenderPipeline> createRenderPipelineAsync(GPURenderPipelineDescriptor descriptor);

    GPUCommandEncoder createCommandEncoder(optional GPUCommandEncoderDescriptor descriptor = {});
    GPURenderBundleEncoder createRenderBundleEncoder(GPURenderBundleEncoderDescriptor descriptor);

    GPUQuerySet createQuerySet(GPUQuerySetDescriptor descriptor);
};
GPUDevice includes GPUObjectBase;

[Exposed=(Window, Worker), SecureContext]
interface GPUBuffer {
    readonly attribute GPUSize64Out size;
    readonly attribute GPUFlagsConstant usage;

    readonly attribute GPUBufferMapState mapState;

    Promise<undefined> mapAsync(GPUMapModeFlags mode, optional GPUSize64 offset = 0, optional GPUSize64 size);
    ArrayBuffer getMappedRange(optional GPUSize64 offset = 0, optional GPUSize64 size);
    undefined unmap();

    undefined destroy();
};
GPUBuffer includes GPUObjectBase;

enum GPUBufferMapState {
    "unmapped",
    "pending",
    "mapped",
};

dictionary GPUBufferDescriptor
         : GPUObjectDescriptorBase {
    required GPUSize64 size;
    required GPUBufferUsageFlags usage;
    boolean mappedAtCreation = false;
};

typedef [EnforceRange] unsigned long GPUBufferUsageFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUBufferUsage {
    const GPUFlagsConstant MAP_READ      = 0x0001;
    const GPUFlagsConstant MAP_WRITE     = 0x0002;
    const GPUFlagsConstant COPY_SRC      = 0x0004;
    const GPUFlagsConstant COPY_DST      = 0x0008;
    const GPUFlagsConstant INDEX         = 0x0010;
    const GPUFlagsConstant VERTEX        = 0x0020;
    const GPUFlagsConstant UNIFORM       = 0x0040;
    const GPUFlagsConstant STORAGE       = 0x0080;
    const GPUFlagsConstant INDIRECT      = 0x0100;
    const GPUFlagsConstant QUERY_RESOLVE = 0x0200;
};

typedef [EnforceRange] unsigned long GPUMapModeFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUMapMode {
    const GPUFlagsConstant READ  = 0x0001;
    const GPUFlagsConstant WRITE = 0x0002;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUTexture {
    GPUTextureView createView(optional GPUTextureViewDescriptor descriptor = {});

    undefined destroy();

    readonly attribute GPUIntegerCoordinateOut width;
    readonly attribute GPUIntegerCoordinateOut height;
    readonly attribute GPUIntegerCoordinateOut depthOrArrayLayers;
    readonly attribute GPUIntegerCoordinateOut mipLevelCount;
    readonly attribute GPUSize32Out sampleCount;
    readonly attribute GPUTextureDimension dimension;
    readonly attribute GPUTextureFormat format;
    readonly attribute GPUFlagsConstant usage;
};
GPUTexture includes GPUObjectBase;

dictionary GPUTextureDescriptor
         : GPUObjectDescriptorBase {
    required GPUExtent3D size;
    GPUIntegerCoordinate mipLevelCount = 1;
    GPUSize32 sampleCount = 1;
    GPUTextureDimension dimension = "2d";
    required GPUTextureFormat format;
    required GPUTextureUsageFlags usage;
    sequence<GPUTextureFormat> viewFormats = [];
};

enum GPUTextureDimension {
    "1d",
    "2d",
    "3d",
};

typedef [EnforceRange] unsigned long GPUTextureUsageFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUTextureUsage {
    const GPUFlagsConstant COPY_SRC          = 0x01;
    const GPUFlagsConstant COPY_DST          = 0x02;
    const GPUFlagsConstant TEXTURE_BINDING   = 0x04;
    const GPUFlagsConstant STORAGE_BINDING   = 0x08;
    const GPUFlagsConstant RENDER_ATTACHMENT = 0x10;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUTextureView {
};
GPUTextureView includes GPUObjectBase;

dictionary GPUTextureViewDescriptor
         : GPUObjectDescriptorBase {
    GPUTextureFormat format;
    GPUTextureViewDimension dimension;
    GPUTextureUsageFlags usage = 0;
    GPUTextureAspect aspect = "all";
    GPUIntegerCoordinate baseMipLevel = 0;
    GPUIntegerCoordinate mipLevelCount;
    GPUIntegerCoordinate baseArrayLayer = 0;
    GPUIntegerCoordinate arrayLayerCount;
};

enum GPUTextureViewDimension {
    "1d",
    "2d",
    "2d-array",
    "cube",
    "cube-array",
    "3d",
};

enum GPUTextureAspect {
    "all",
    "stencil-only",
    "depth-only",
};

enum GPUTextureFormat {
    // 8-bit formats
    "r8unorm",
    "r8snorm",
    "r8uint",
    "r8sint",

    // 16-bit formats
    "r16uint",
    "r16sint",
    "r16float",
    "rg8unorm",
    "rg8snorm",
    "rg8uint",
    "rg8sint",

    // 32-bit formats
    "r32uint",
    "r32sint",
    "r32float",
    "rg16uint",
    "rg16sint",
    "rg16float",
    "rgba8unorm",
    "rgba8unorm-srgb",
    "rgba8snorm",
    "rgba8uint",
    "rgba8sint",
    "bgra8unorm",
    "bgra8unorm-srgb",
    // Packed 32-bit formats
    "rgb9e5ufloat",
    "rgb10a2uint",
    "rgb10a2unorm",
    "rg11b10ufloat",

    // 64-bit formats
    "rg32uint",
    "rg32sint",
    "rg32float",
    "rgba16uint",
    "rgba16sint",
    "rgba16float",

    // 128-bit formats
    "rgba32uint",
    "rgba32sint",
    "rgba32float",

    // Depth/stencil formats
    "stencil8",
    "depth16unorm",
    "depth24plus",
    "depth24plus-stencil8",
    "depth32float",

    // "depth32float-stencil8" feature
    "depth32float-stencil8",

    // BC compressed formats usable if "texture-compression-bc" is both
    // supported by the device/user agent and enabled in requestDevice.
    "bc1-rgba-unorm",
    "bc1-rgba-unorm-srgb",
    "bc2-rgba-unorm",
    "bc2-rgba-unorm-srgb",
    "bc3-rgba-unorm",
    "bc3-rgba-unorm-srgb",
    "bc4-r-unorm",
    "bc4-r-snorm",
    "bc5-rg-unorm",
    "bc5-rg-snorm",
    "bc6h-rgb-ufloat",
    "bc6h-rgb-float",
    "bc7-rgba-unorm",
    "bc7-rgba-unorm-srgb",

    // ETC2 compressed formats usable if "texture-compression-etc2" is both
    // supported by the device/user agent and enabled in requestDevice.
    "etc2-rgb8unorm",
    "etc2-rgb8unorm-srgb",
    "etc2-rgb8a1unorm",
    "etc2-rgb8a1unorm-srgb",
    "etc2-rgba8unorm",
    "etc2-rgba8unorm-srgb",
    "eac-r11unorm",
    "eac-r11snorm",
    "eac-rg11unorm",
    "eac-rg11snorm",

    // ASTC compressed formats usable if "texture-compression-astc" is both
    // supported by the device/user agent and enabled in requestDevice.
    "astc-4x4-unorm",
    "astc-4x4-unorm-srgb",
    "astc-5x4-unorm",
    "astc-5x4-unorm-srgb",
    "astc-5x5-unorm",
    "astc-5x5-unorm-srgb",
    "astc-6x5-unorm",
    "astc-6x5-unorm-srgb",
    "astc-6x6-unorm",
    "astc-6x6-unorm-srgb",
    "astc-8x5-unorm",
    "astc-8x5-unorm-srgb",
    "astc-8x6-unorm",
    "astc-8x6-unorm-srgb",
    "astc-8x8-unorm",
    "astc-8x8-unorm-srgb",
    "astc-10x5-unorm",
    "astc-10x5-unorm-srgb",
    "astc-10x6-unorm",
    "astc-10x6-unorm-srgb",
    "astc-10x8-unorm",
    "astc-10x8-unorm-srgb",
    "astc-10x10-unorm",
    "astc-10x10-unorm-srgb",
    "astc-12x10-unorm",
    "astc-12x10-unorm-srgb",
    "astc-12x12-unorm",
    "astc-12x12-unorm-srgb",
};

[Exposed=(Window, Worker), SecureContext]
interface GPUExternalTexture {
};
GPUExternalTexture includes GPUObjectBase;

dictionary GPUExternalTextureDescriptor
         : GPUObjectDescriptorBase {
    required (HTMLVideoElement or VideoFrame) source;
    PredefinedColorSpace colorSpace = "srgb";
};

[Exposed=(Window, Worker), SecureContext]
interface GPUSampler {
};
GPUSampler includes GPUObjectBase;

dictionary GPUSamplerDescriptor
         : GPUObjectDescriptorBase {
    GPUAddressMode addressModeU = "clamp-to-edge";
    GPUAddressMode addressModeV = "clamp-to-edge";
    GPUAddressMode addressModeW = "clamp-to-edge";
    GPUFilterMode magFilter = "nearest";
    GPUFilterMode minFilter = "nearest";
    GPUMipmapFilterMode mipmapFilter = "nearest";
    float lodMinClamp = 0;
    float lodMaxClamp = 32;
    GPUCompareFunction compare;
    [Clamp] unsigned short maxAnisotropy = 1;
};

enum GPUAddressMode {
    "clamp-to-edge",
    "repeat",
    "mirror-repeat",
};

enum GPUFilterMode {
    "nearest",
    "linear",
};

enum GPUMipmapFilterMode {
    "nearest",
    "linear",
};

enum GPUCompareFunction {
    "never",
    "less",
    "equal",
    "less-equal",
    "greater",
    "not-equal",
    "greater-equal",
    "always",
};

[Exposed=(Window, Worker), SecureContext]
interface GPUBindGroupLayout {
};
GPUBindGroupLayout includes GPUObjectBase;

dictionary GPUBindGroupLayoutDescriptor
         : GPUObjectDescriptorBase {
    required sequence<GPUBindGroupLayoutEntry> entries;
};

dictionary GPUBindGroupLayoutEntry {
    required GPUIndex32 binding;
    required GPUShaderStageFlags visibility;

    GPUBufferBindingLayout buffer;
    GPUSamplerBindingLayout sampler;
    GPUTextureBindingLayout texture;
    GPUStorageTextureBindingLayout storageTexture;
    GPUExternalTextureBindingLayout externalTexture;
};

typedef [EnforceRange] unsigned long GPUShaderStageFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUShaderStage {
    const GPUFlagsConstant VERTEX   = 0x1;
    const GPUFlagsConstant FRAGMENT = 0x2;
    const GPUFlagsConstant COMPUTE  = 0x4;
};

enum GPUBufferBindingType {
    "uniform",
    "storage",
    "read-only-storage",
};

dictionary GPUBufferBindingLayout {
    GPUBufferBindingType type = "uniform";
    boolean hasDynamicOffset = false;
    GPUSize64 minBindingSize = 0;
};

enum GPUSamplerBindingType {
    "filtering",
    "non-filtering",
    "comparison",
};

dictionary GPUSamplerBindingLayout {
    GPUSamplerBindingType type = "filtering";
};

enum GPUTextureSampleType {
    "float",
    "unfilterable-float",
    "depth",
    "sint",
    "uint",
};

dictionary GPUTextureBindingLayout {
    GPUTextureSampleType sampleType = "float";
    GPUTextureViewDimension viewDimension = "2d";
    boolean multisampled = false;
};

enum GPUStorageTextureAccess {
    "write-only",
    "read-only",
    "read-write",
};

dictionary GPUStorageTextureBindingLayout {
    GPUStorageTextureAccess access = "write-only";
    required GPUTextureFormat format;
    GPUTextureViewDimension viewDimension = "2d";
};

dictionary GPUExternalTextureBindingLayout {
};

[Exposed=(Window, Worker), SecureContext]
interface GPUBindGroup {
};
GPUBindGroup includes GPUObjectBase;

dictionary GPUBindGroupDescriptor
         : GPUObjectDescriptorBase {
    required GPUBindGroupLayout layout;
    required sequence<GPUBindGroupEntry> entries;
};

typedef (GPUSampler or GPUTextureView or GPUBufferBinding or GPUExternalTexture) GPUBindingResource;

dictionary GPUBindGroupEntry {
    required GPUIndex32 binding;
    required GPUBindingResource resource;
};

dictionary GPUBufferBinding {
    required GPUBuffer buffer;
    GPUSize64 offset = 0;
    GPUSize64 size;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUPipelineLayout {
};
GPUPipelineLayout includes GPUObjectBase;

dictionary GPUPipelineLayoutDescriptor
         : GPUObjectDescriptorBase {
    required sequence<GPUBindGroupLayout> bindGroupLayouts;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUShaderModule {
    Promise<GPUCompilationInfo> getCompilationInfo();
};
GPUShaderModule includes GPUObjectBase;

dictionary GPUShaderModuleDescriptor
         : GPUObjectDescriptorBase {
    required USVString code;
    sequence<GPUShaderModuleCompilationHint> compilationHints = [];
};

dictionary GPUShaderModuleCompilationHint {
    required USVString entryPoint;
    (GPUPipelineLayout or GPUAutoLayoutMode) layout;
};

enum GPUCompilationMessageType {
    "error",
    "warning",
    "info",
};

[Exposed=(Window, Worker), Serializable, SecureContext]
interface GPUCompilationMessage {
    readonly attribute DOMString message;
    readonly attribute GPUCompilationMessageType type;
    readonly attribute unsigned long long lineNum;
    readonly attribute unsigned long long linePos;
    readonly attribute unsigned long long offset;
    readonly attribute unsigned long long length;
};

[Exposed=(Window, Worker), Serializable, SecureContext]
interface GPUCompilationInfo {
    readonly attribute FrozenArray<GPUCompilationMessage> messages;
};

[Exposed=(Window, Worker), SecureContext, Serializable]
interface GPUPipelineError : DOMException {
    constructor(optional DOMString message = "", GPUPipelineErrorInit options);
    readonly attribute GPUPipelineErrorReason reason;
};

dictionary GPUPipelineErrorInit {
    required GPUPipelineErrorReason reason;
};

enum GPUPipelineErrorReason {
    "validation",
    "internal",
};

enum GPUAutoLayoutMode {
    "auto",
};

dictionary GPUPipelineDescriptorBase
         : GPUObjectDescriptorBase {
    required (GPUPipelineLayout or GPUAutoLayoutMode) layout;
};

interface mixin GPUPipelineBase {
    [NewObject] GPUBindGroupLayout getBindGroupLayout(unsigned long index);
};

dictionary GPUProgrammableStage {
    required GPUShaderModule module;
    USVString entryPoint;
    record<USVString, GPUPipelineConstantValue> constants = {};
};

typedef double GPUPipelineConstantValue; // May represent WGSL's bool, f32, i32, u32, and f16 if enabled.

[Exposed=(Window, Worker), SecureContext]
interface GPUComputePipeline {
};
GPUComputePipeline includes GPUObjectBase;
GPUComputePipeline includes GPUPipelineBase;

dictionary GPUComputePipelineDescriptor
         : GPUPipelineDescriptorBase {
    required GPUProgrammableStage compute;
};

[Exposed=(Window, Worker), SecureContext]
interface GPURenderPipeline {
};
GPURenderPipeline includes GPUObjectBase;
GPURenderPipeline includes GPUPipelineBase;

dictionary GPURenderPipelineDescriptor
         : GPUPipelineDescriptorBase {
    required GPUVertexState vertex;
    GPUPrimitiveState primitive = {};
    GPUDepthStencilState depthStencil;
    GPUMultisampleState multisample = {};
    GPUFragmentState fragment;
};

dictionary GPUPrimitiveState {
    GPUPrimitiveTopology topology = "triangle-list";
    GPUIndexFormat stripIndexFormat;
    GPUFrontFace frontFace = "ccw";
    GPUCullMode cullMode = "none";

    // Requires "depth-clip-control" feature.
    boolean unclippedDepth = false;
};

enum GPUPrimitiveTopology {
    "point-list",
    "line-list",
    "line-strip",
    "triangle-list",
    "triangle-strip",
};

enum GPUFrontFace {
    "ccw",
    "cw",
};

enum GPUCullMode {
    "none",
    "front",
    "back",
};

dictionary GPUMultisampleState {
    GPUSize32 count = 1;
    GPUSampleMask mask = 0xFFFFFFFF;
    boolean alphaToCoverageEnabled = false;
};

dictionary GPUFragmentState
         : GPUProgrammableStage {
    required sequence<GPUColorTargetState?> targets;
};

dictionary GPUColorTargetState {
    required GPUTextureFormat format;

    GPUBlendState blend;
    GPUColorWriteFlags writeMask = 0xF;  // GPUColorWrite.ALL
};

dictionary GPUBlendState {
    required GPUBlendComponent color;
    required GPUBlendComponent alpha;
};

typedef [EnforceRange] unsigned long GPUColorWriteFlags;
[Exposed=(Window, Worker), SecureContext]
namespace GPUColorWrite {
    const GPUFlagsConstant RED   = 0x1;
    const GPUFlagsConstant GREEN = 0x2;
    const GPUFlagsConstant BLUE  = 0x4;
    const GPUFlagsConstant ALPHA = 0x8;
    const GPUFlagsConstant ALL   = 0xF;
};

dictionary GPUBlendComponent {
    GPUBlendOperation operation = "add";
    GPUBlendFactor srcFactor = "one";
    GPUBlendFactor dstFactor = "zero";
};

enum GPUBlendFactor {
    "zero",
    "one",
    "src",
    "one-minus-src",
    "src-alpha",
    "one-minus-src-alpha",
    "dst",
    "one-minus-dst",
    "dst-alpha",
    "one-minus-dst-alpha",
    "src-alpha-saturated",
    "constant",
    "one-minus-constant",
    "src1",
    "one-minus-src1",
    "src1-alpha",
    "one-minus-src1-alpha",
};

enum GPUBlendOperation {
    "add",
    "subtract",
    "reverse-subtract",
    "min",
    "max",
};

dictionary GPUDepthStencilState {
    required GPUTextureFormat format;

    boolean depthWriteEnabled;
    GPUCompareFunction depthCompare;

    GPUStencilFaceState stencilFront = {};
    GPUStencilFaceState stencilBack = {};

    GPUStencilValue stencilReadMask = 0xFFFFFFFF;
    GPUStencilValue stencilWriteMask = 0xFFFFFFFF;

    GPUDepthBias depthBias = 0;
    float depthBiasSlopeScale = 0;
    float depthBiasClamp = 0;
};

dictionary GPUStencilFaceState {
    GPUCompareFunction compare = "always";
    GPUStencilOperation failOp = "keep";
    GPUStencilOperation depthFailOp = "keep";
    GPUStencilOperation passOp = "keep";
};

enum GPUStencilOperation {
    "keep",
    "zero",
    "replace",
    "invert",
    "increment-clamp",
    "decrement-clamp",
    "increment-wrap",
    "decrement-wrap",
};

enum GPUIndexFormat {
    "uint16",
    "uint32",
};

enum GPUVertexFormat {
    "uint8x2",
    "uint8x4",
    "sint8x2",
    "sint8x4",
    "unorm8x2",
    "unorm8x4",
    "snorm8x2",
    "snorm8x4",
    "uint16x2",
    "uint16x4",
    "sint16x2",
    "sint16x4",
    "unorm16x2",
    "unorm16x4",
    "snorm16x2",
    "snorm16x4",
    "float16x2",
    "float16x4",
    "float32",
    "float32x2",
    "float32x3",
    "float32x4",
    "uint32",
    "uint32x2",
    "uint32x3",
    "uint32x4",
    "sint32",
    "sint32x2",
    "sint32x3",
    "sint32x4",
    "unorm10-10-10-2",
};

enum GPUVertexStepMode {
    "vertex",
    "instance",
};

dictionary GPUVertexState
         : GPUProgrammableStage {
    sequence<GPUVertexBufferLayout?> buffers = [];
};

dictionary GPUVertexBufferLayout {
    required GPUSize64 arrayStride;
    GPUVertexStepMode stepMode = "vertex";
    required sequence<GPUVertexAttribute> attributes;
};

dictionary GPUVertexAttribute {
    required GPUVertexFormat format;
    required GPUSize64 offset;

    required GPUIndex32 shaderLocation;
};

dictionary GPUTexelCopyBufferLayout {
    GPUSize64 offset = 0;
    GPUSize32 bytesPerRow;
    GPUSize32 rowsPerImage;
};

dictionary GPUTexelCopyBufferInfo
         : GPUTexelCopyBufferLayout {
    required GPUBuffer buffer;
};

dictionary GPUTexelCopyTextureInfo {
    required GPUTexture texture;
    GPUIntegerCoordinate mipLevel = 0;
    GPUOrigin3D origin = {};
    GPUTextureAspect aspect = "all";
};

dictionary GPUCopyExternalImageDestInfo
         : GPUTexelCopyTextureInfo {
    PredefinedColorSpace colorSpace = "srgb";
    boolean premultipliedAlpha = false;
};

typedef (ImageBitmap or
         ImageData or
         HTMLImageElement or
         HTMLVideoElement or
         VideoFrame or
         HTMLCanvasElement or
         OffscreenCanvas) GPUCopyExternalImageSource;

dictionary GPUCopyExternalImageSourceInfo {
    required GPUCopyExternalImageSource source;
    GPUOrigin2D origin = {};
    boolean flipY = false;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUCommandBuffer {
};
GPUCommandBuffer includes GPUObjectBase;

dictionary GPUCommandBufferDescriptor
         : GPUObjectDescriptorBase {
};

interface mixin GPUCommandsMixin {
};

[Exposed=(Window, Worker), SecureContext]
interface GPUCommandEncoder {
    GPURenderPassEncoder beginRenderPass(GPURenderPassDescriptor descriptor);
    GPUComputePassEncoder beginComputePass(optional GPUComputePassDescriptor descriptor = {});

    undefined copyBufferToBuffer(
        GPUBuffer source,
        GPUSize64 sourceOffset,
        GPUBuffer destination,
        GPUSize64 destinationOffset,
        GPUSize64 size);

    undefined copyBufferToTexture(
        GPUTexelCopyBufferInfo source,
        GPUTexelCopyTextureInfo destination,
        GPUExtent3D copySize);

    undefined copyTextureToBuffer(
        GPUTexelCopyTextureInfo source,
        GPUTexelCopyBufferInfo destination,
        GPUExtent3D copySize);

    undefined copyTextureToTexture(
        GPUTexelCopyTextureInfo source,
        GPUTexelCopyTextureInfo destination,
        GPUExtent3D copySize);

    undefined clearBuffer(
        GPUBuffer buffer,
        optional GPUSize64 offset = 0,
        optional GPUSize64 size);

    undefined resolveQuerySet(
        GPUQuerySet querySet,
        GPUSize32 firstQuery,
        GPUSize32 queryCount,
        GPUBuffer destination,
        GPUSize64 destinationOffset);

    GPUCommandBuffer finish(optional GPUCommandBufferDescriptor descriptor = {});
};
GPUCommandEncoder includes GPUObjectBase;
GPUCommandEncoder includes GPUCommandsMixin;
GPUCommandEncoder includes GPUDebugCommandsMixin;

dictionary GPUCommandEncoderDescriptor
         : GPUObjectDescriptorBase {
};

interface mixin GPUBindingCommandsMixin {
    undefined setBindGroup(GPUIndex32 index, GPUBindGroup? bindGroup,
        optional sequence<GPUBufferDynamicOffset> dynamicOffsets = []);

    undefined setBindGroup(GPUIndex32 index, GPUBindGroup? bindGroup,
        Uint32Array dynamicOffsetsData,
        GPUSize64 dynamicOffsetsDataStart,
        GPUSize32 dynamicOffsetsDataLength);
};

interface mixin GPUDebugCommandsMixin {
    undefined pushDebugGroup(USVString groupLabel);
    undefined popDebugGroup();
    undefined insertDebugMarker(USVString markerLabel);
};

[Exposed=(Window, Worker), SecureContext]
interface GPUComputePassEncoder {
    undefined setPipeline(GPUComputePipeline pipeline);
    undefined dispatchWorkgroups(GPUSize32 workgroupCountX, optional GPUSize32 workgroupCountY = 1, optional GPUSize32 workgroupCountZ = 1);
    undefined dispatchWorkgroupsIndirect(GPUBuffer indirectBuffer, GPUSize64 indirectOffset);

    undefined end();
};
GPUComputePassEncoder includes GPUObjectBase;
GPUComputePassEncoder includes GPUCommandsMixin;
GPUComputePassEncoder includes GPUDebugCommandsMixin;
GPUComputePassEncoder includes GPUBindingCommandsMixin;

dictionary GPUComputePassTimestampWrites {
    required GPUQuerySet querySet;
    GPUSize32 beginningOfPassWriteIndex;
    GPUSize32 endOfPassWriteIndex;
};

dictionary GPUComputePassDescriptor
         : GPUObjectDescriptorBase {
    GPUComputePassTimestampWrites timestampWrites;
};

[Exposed=(Window, Worker), SecureContext]
interface GPURenderPassEncoder {
    undefined setViewport(float x, float y,
        float width, float height,
        float minDepth, float maxDepth);

    undefined setScissorRect(GPUIntegerCoordinate x, GPUIntegerCoordinate y,
                        GPUIntegerCoordinate width, GPUIntegerCoordinate height);

    undefined setBlendConstant(GPUColor color);
    undefined setStencilReference(GPUStencilValue reference);

    undefined beginOcclusionQuery(GPUSize32 queryIndex);
    undefined endOcclusionQuery();

    undefined executeBundles(sequence<GPURenderBundle> bundles);
    undefined end();
};
GPURenderPassEncoder includes GPUObjectBase;
GPURenderPassEncoder includes GPUCommandsMixin;
GPURenderPassEncoder includes GPUDebugCommandsMixin;
GPURenderPassEncoder includes GPUBindingCommandsMixin;
GPURenderPassEncoder includes GPURenderCommandsMixin;

dictionary GPURenderPassTimestampWrites {
    required GPUQuerySet querySet;
    GPUSize32 beginningOfPassWriteIndex;
    GPUSize32 endOfPassWriteIndex;
};

dictionary GPURenderPassDescriptor
         : GPUObjectDescriptorBase {
    required sequence<GPURenderPassColorAttachment?> colorAttachments;
    GPURenderPassDepthStencilAttachment depthStencilAttachment;
    GPUQuerySet occlusionQuerySet;
    GPURenderPassTimestampWrites timestampWrites;
    GPUSize64 maxDrawCount = 50000000;
};

dictionary GPURenderPassColorAttachment {
    required GPUTextureView view;
    GPUIntegerCoordinate depthSlice;
    GPUTextureView resolveTarget;

    GPUColor clearValue;
    required GPULoadOp loadOp;
    required GPUStoreOp storeOp;
};

dictionary GPURenderPassDepthStencilAttachment {
    required GPUTextureView view;

    float depthClearValue;
    GPULoadOp depthLoadOp;
    GPUStoreOp depthStoreOp;
    boolean depthReadOnly = false;

    GPUStencilValue stencilClearValue = 0;
    GPULoadOp stencilLoadOp;
    GPUStoreOp stencilStoreOp;
    boolean stencilReadOnly = false;
};

enum GPULoadOp {
    "load",
    "clear",
};

enum GPUStoreOp {
    "store",
    "discard",
};

dictionary GPURenderPassLayout
         : GPUObjectDescriptorBase {
    required sequence<GPUTextureFormat?> colorFormats;
    GPUTextureFormat depthStencilFormat;
    GPUSize32 sampleCount = 1;
};

interface mixin GPURenderCommandsMixin {
    undefined setPipeline(GPURenderPipeline pipeline);

    undefined setIndexBuffer(GPUBuffer buffer, GPUIndexFormat indexFormat, optional GPUSize64 offset = 0, optional GPUSize64 size);
    undefined setVertexBuffer(GPUIndex32 slot, GPUBuffer? buffer, optional GPUSize64 offset = 0, optional GPUSize64 size);

    undefined draw(GPUSize32 vertexCount, optional GPUSize32 instanceCount = 1,
        optional GPUSize32 firstVertex = 0, optional GPUSize32 firstInstance = 0);
    undefined drawIndexed(GPUSize32 indexCount, optional GPUSize32 instanceCount = 1,
        optional GPUSize32 firstIndex = 0,
        optional GPUSignedOffset32 baseVertex = 0,
        optional GPUSize32 firstInstance = 0);

    undefined drawIndirect(GPUBuffer indirectBuffer, GPUSize64 indirectOffset);
    undefined drawIndexedIndirect(GPUBuffer indirectBuffer, GPUSize64 indirectOffset);
};

[Exposed=(Window, Worker), SecureContext]
interface GPURenderBundle {
};
GPURenderBundle includes GPUObjectBase;

dictionary GPURenderBundleDescriptor
         : GPUObjectDescriptorBase {
};

[Exposed=(Window, Worker), SecureContext]
interface GPURenderBundleEncoder {
    GPURenderBundle finish(optional GPURenderBundleDescriptor descriptor = {});
};
GPURenderBundleEncoder includes GPUObjectBase;
GPURenderBundleEncoder includes GPUCommandsMixin;
GPURenderBundleEncoder includes GPUDebugCommandsMixin;
GPURenderBundleEncoder includes GPUBindingCommandsMixin;
GPURenderBundleEncoder includes GPURenderCommandsMixin;

dictionary GPURenderBundleEncoderDescriptor
         : GPURenderPassLayout {
    boolean depthReadOnly = false;
    boolean stencilReadOnly = false;
};

dictionary GPUQueueDescriptor
         : GPUObjectDescriptorBase {
};

[Exposed=(Window, Worker), SecureContext]
interface GPUQueue {
    undefined submit(sequence<GPUCommandBuffer> commandBuffers);

    Promise<undefined> onSubmittedWorkDone();

    undefined writeBuffer(
        GPUBuffer buffer,
        GPUSize64 bufferOffset,
        AllowSharedBufferSource data,
        optional GPUSize64 dataOffset = 0,
        optional GPUSize64 size);

    undefined writeTexture(
        GPUTexelCopyTextureInfo destination,
        AllowSharedBufferSource data,
        GPUTexelCopyBufferLayout dataLayout,
        GPUExtent3D size);

    undefined copyExternalImageToTexture(
        GPUCopyExternalImageSourceInfo source,
        GPUCopyExternalImageDestInfo destination,
        GPUExtent3D copySize);
};
GPUQueue includes GPUObjectBase;

[Exposed=(Window, Worker), SecureContext]
interface GPUQuerySet {
    undefined destroy();

    readonly attribute GPUQueryType type;
    readonly attribute GPUSize32Out count;
};
GPUQuerySet includes GPUObjectBase;

dictionary GPUQuerySetDescriptor
         : GPUObjectDescriptorBase {
    required GPUQueryType type;
    required GPUSize32 count;
};

enum GPUQueryType {
    "occlusion",
    "timestamp",
};

[Exposed=(Window, Worker), SecureContext]
interface GPUCanvasContext {
    readonly attribute (HTMLCanvasElement or OffscreenCanvas) canvas;

    undefined configure(GPUCanvasConfiguration configuration);
    undefined unconfigure();

    GPUCanvasConfiguration? getConfiguration();
    GPUTexture getCurrentTexture();
};

enum GPUCanvasAlphaMode {
    "opaque",
    "premultiplied",
};

enum GPUCanvasToneMappingMode {
    "standard",
    "extended",
};

dictionary GPUCanvasToneMapping {
  GPUCanvasToneMappingMode mode = "standard";
};

dictionary GPUCanvasConfiguration {
    required GPUDevice device;
    required GPUTextureFormat format;
    GPUTextureUsageFlags usage = 0x10;  // GPUTextureUsage.RENDER_ATTACHMENT
    sequence<GPUTextureFormat> viewFormats = [];
    PredefinedColorSpace colorSpace = "srgb";
    GPUCanvasToneMapping toneMapping = {};
    GPUCanvasAlphaMode alphaMode = "opaque";
};

enum GPUDeviceLostReason {
    "unknown",
    "destroyed",
};

[Exposed=(Window, Worker), SecureContext]
interface GPUDeviceLostInfo {
    readonly attribute GPUDeviceLostReason reason;
    readonly attribute DOMString message;
};

partial interface GPUDevice {
    readonly attribute Promise<GPUDeviceLostInfo> lost;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUError {
    readonly attribute DOMString message;
};

[Exposed=(Window, Worker), SecureContext]
interface GPUValidationError
        : GPUError {
    constructor(DOMString message);
};

[Exposed=(Window, Worker), SecureContext]
interface GPUOutOfMemoryError
        : GPUError {
    constructor(DOMString message);
};

[Exposed=(Window, Worker), SecureContext]
interface GPUInternalError
        : GPUError {
    constructor(DOMString message);
};

enum GPUErrorFilter {
    "validation",
    "out-of-memory",
    "internal",
};

partial interface GPUDevice {
    undefined pushErrorScope(GPUErrorFilter filter);
    Promise<GPUError?> popErrorScope();
};

[Exposed=(Window, Worker), SecureContext]
interface GPUUncapturedErrorEvent : Event {
    constructor(
        DOMString type,
        GPUUncapturedErrorEventInit gpuUncapturedErrorEventInitDict
    );
    [SameObject] readonly attribute GPUError error;
};

dictionary GPUUncapturedErrorEventInit : EventInit {
    required GPUError error;
};

partial interface GPUDevice {
    attribute EventHandler onuncapturederror;
};

typedef [EnforceRange] unsigned long GPUBufferDynamicOffset;
typedef [EnforceRange] unsigned long GPUStencilValue;
typedef [EnforceRange] unsigned long GPUSampleMask;
typedef [EnforceRange] long GPUDepthBias;

typedef [EnforceRange] unsigned long long GPUSize64;
typedef [EnforceRange] unsigned long GPUIntegerCoordinate;
typedef [EnforceRange] unsigned long GPUIndex32;
typedef [EnforceRange] unsigned long GPUSize32;
typedef [EnforceRange] long GPUSignedOffset32;

typedef unsigned long long GPUSize64Out;
typedef unsigned long GPUIntegerCoordinateOut;
typedef unsigned long GPUSize32Out;

typedef unsigned long GPUFlagsConstant;

dictionary GPUColorDict {
    required double r;
    required double g;
    required double b;
    required double a;
};
typedef (sequence<double> or GPUColorDict) GPUColor;

dictionary GPUOrigin2DDict {
    GPUIntegerCoordinate x = 0;
    GPUIntegerCoordinate y = 0;
};
typedef (sequence<GPUIntegerCoordinate> or GPUOrigin2DDict) GPUOrigin2D;

dictionary GPUOrigin3DDict {
    GPUIntegerCoordinate x = 0;
    GPUIntegerCoordinate y = 0;
    GPUIntegerCoordinate z = 0;
};
typedef (sequence<GPUIntegerCoordinate> or GPUOrigin3DDict) GPUOrigin3D;

dictionary GPUExtent3DDict {
    required GPUIntegerCoordinate width;
    GPUIntegerCoordinate height = 1;
    GPUIntegerCoordinate depthOrArrayLayers = 1;
};
typedef (sequence<GPUIntegerCoordinate> or GPUExtent3DDict) GPUExtent3D;